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The Fate of Heterotopically Grafted Neural Precursor Cells in the Normal and Dystrophic Adult Mouse Retina

¹ From the Universitätsklinikum Eppendorf (UKE) Augenklinik and ² Zentrum für Molekulare Neurobiologie, Universität Hamburg, Germany.

	Abstract

Top Abstract Introduction Methods Results Discussion References

 
PURPOSE. To study the integration and differentiation of heterotopically transplanted neural precursor cells in the retina of adult mouse mutants displaying apoptotic degeneration of photoreceptor cells.

METHODS. Neural precursor cells were isolated from the spinal cord of transgenic mouse embryos ubiquitously expressing enhanced green fluorescent protein. Cells were expanded in vitro and transplanted into the retina of adult wild-type and age-matched ß2/ß1 knock-in mice. ß2/ß1 knock-in mutants display apoptotic death of photoreceptor cells and were generated by placing the cDNA of the ß1 subunit into the gene of the ß2 subunit of Na,K-ATPase. The integration and differentiation of grafted cells in recipient retinas was studied 1 or 6 months after transplantation.

RESULTS. Mutant retinas contained more donor-derived cells than wild-type hosts. Moreover, in mutants, donor cells integrated into deeper retinal layers. In both genotypes, grafted cells differentiated into astrocytes and oligodendrocytes. Only a few ganglion cell axons were myelinated by donor-derived oligodendrocytes 1 month after transplantation, whereas extensive myelination of the nerve fiber layer was observed 6 months after transplantation. Unequivocal evidence for differentiation of grafted cells into neurons was not obtained.

CONCLUSIONS. Heterotopically transplanted neural precursor cells are capable of integrating, surviving, and differentiating into neural cell types in normal and dystrophic retinas of adult mice. The particular environment of a pathologically altered retina facilitates integration of transplanted precursor cells. In principle, neural precursors may thus be useful to substitute for or replace dysfunctional or degenerated cell types. Results of the present study also indicate that replacement of retinal cell types is likely to require more appropriate donor cells, such as retinal precursor cells.

	Introduction

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Inherited retinal dystrophies are a heterogeneous group of disorders characterized by progressive retinal degeneration. Effective therapeutic treatments of retinal dystrophies in humans are currently not available. However, animal experiments have shown beneficial effects of various therapeutic strategies, including gene therapy to substitute for the pathogenic gene, application of growth factors to minimize cell degeneration, or transplantation of committed cell types to replace dysfunctional or degenerated cells.^{1 2 3 4 5}

Transplantation of neural precursor cells instead of committed neural cell types is emerging as an additional, promising approach to replace dysfunctional or degenerated cell types in the nervous system. Neural precursors are multipotential cells and give rise to neurons, astrocytes, and oligodendrocytes.^{6 7 8 9} These cells display a markedly broader differentiation potential. When exposed to appropriate external stimuli, they are also capable of differentiating into diverse non-neural cell types of all germ layers.^{10 11 12} Neural precursors have been isolated from the developing and adult brain and can be massively expanded in vitro, providing, in principle, unlimited amounts of cell material for transplantation (different from primary retinal cells). When transplanted into the developing or adult brain, they have been demonstrated to integrate extensively into the recipient tissue, to survive for extended periods, and to eventually differentiate into those cell types that are affected in the host.^{13 14 15 16 17 18 19} Neural precursor cells have also been successfully used as cellular vehicles, to introduce therapeutic gene products into the diseased nervous tissue.^{20 21}

To study the integration and differentiation of multipotent precursor cells in a dystrophic adult retina, we isolated spinal precursors from transgenic mouse embryos ubiquitously expressing enhanced green fluorescent protein (EGFP).²² These cells were expanded in vitro in the presence of mitogens and subsequently transplanted into the retina of adult wild-type mice and mouse mutants displaying apoptotic degeneration of photoreceptor cells. As a mutant host, we used ß2/ß1 knock-in mice.²³ ß1 and ß2 are subunits of Na,K-ATPase, a heterodimeric ion pump additionally consisting of a catalytic -subunit.^{23 24} ß-subunits play a pivotal role for the formation of functional Na,K-ATPases as exemplified, for instance, by the severe phenotype of ß2-deficient mice.²⁵ Such mice display a variety of severe defects in the central nervous system (CNS), including massive apoptotic degeneration of photoreceptor cells, and die at the end of the third postnatal week.^{25 26} To study whether the ß1-subunit of Na,K-ATPase is able to functionally substitute for the absence of ß2 expression in vivo, the ß1 gene was inserted into the ß2 gene by homologous recombination in embryonic stem cells.²³ As a result, ß1 is expressed under regulatory elements of the ß2 gene, whereas ß2 expression is abolished. The ß2/ß1 knock-in mutants display a normal life span and an apparently normal development of the brain, with the only obvious exception of a slow and long-lasting apoptotic death of photoreceptor cells. Increased apoptotic degeneration of photoreceptor cells is already apparent in 3-week-old animals and results in a significantly decreased thickness and almost complete atrophy of the outer nuclear layer in 4- and 9-month-old mutants, respectively.²³

To obtain information about the fate of heterotopically transplanted neural precursor cells in the normal and dystrophic mouse retina, we isolated such cells from the spinal cord of EGFP transgenic mice and transplanted them into the retinas of adult wild-type mice and ß2/ß1 knock-in mutants. Heterotopically transplanted neural precursor cells integrated into the mutant retina without disrupting the histoarchitecture of the host tissue. Quantitative investigations revealed that donor-derived cells were more numerous and more widely distributed in mutant retinas than in retinas of age-matched wild-type hosts. Grafted cells survived for extended periods in retinas of both genotypes and differentiated into neural cell types.

	Methods

Top Abstract Introduction Methods Results Discussion References

 
Animals
Transgenic mice ubiquitously expressing EGFP under control of a chicken ß-actin promoter²² were used as donors for neural precursor cells. Animals were maintained on a C57BL/6J genetic background, and transgenic mice were identified by analyzing tail biopsy specimens for the presence of EGFP fluorescence. Neural precursors were transplanted into the retina of adult (6-month-old) wild-type mice (n = 6) and age-matched ß2/ß1 knock-in mutants²³ (n = 6). Four 2-month-old wild-type mice served as additional hosts. Recipient animals were maintained in a C57BL/6J-129/Ola genetic background, and their genotype was determined by Southern blot analysis of DNA isolated from tail specimens as described.²³ All animal experiments were approved by the local animal use committee and were in accordance with the ARVO Statement for the Use of Animals in Ophthalmic and Vision Research.

Cell Culture
Spinal cords were removed from 14-day-old EGFP transgenic mouse embryos. Isolation and cultivation of neural precursors was performed as described elsewhere.^{19 27} In brief, tissue was placed into a defined, serum-free medium composed of a 1:1 mixture of Dulbecco’s modified Eagle’s medium and F-12 (both from Life Technologies, Karlsruhe, Germany) containing glucose (0.6%), glutamine (2 mM), HEPES buffer (5 mM), sodium bicarbonate (3 mM), N2-supplement (1:100; Life Technologies), epidermal growth factor (EGF; 10 ng/ml; Sigma, Deisenhofen, Germany), and basic fibroblast growth factor (FGF-2; 10 ng/ml; Sigma). The tissue was mechanically dissociated using a fire-polished Pasteur pipette, and cells were plated at a density of 200,000 cells/ml in uncoated tissue culture flasks, in the same medium. Cultures were passaged weekly, and cells from the third passage were used for transplantation experiments.

Immunocytochemical Analysis of Cultured Cells
To analyze the differentiation of spinal precursors in vitro, cells were plated on poly-L-lysine–coated glass coverslips and maintained in a culture medium without EGF and FGF-2, but containing 1% fetal calf serum (FCS). Differentiation of neural precursors was analyzed 2 hours or 7 days after plating. Cultures were fixed with 4% paraformaldehyde (PA) in phosphate-buffered saline (PBS; pH 7.3) and incubated with antibodies to cell type–specific markers. Polyclonal rabbit antibodies to nestin (kindly provided by Ron McKay, National Institutes of Health, Bethesda, MD) were used to identify undifferentiated cells, monoclonal mouse antibodies to ß-tubulin type III (Sigma) to identify neurons, monoclonal mouse antibodies to glial fibrillary acidic protein (GFAP; Sigma) to identify astrocytes, and monoclonal mouse antibodies to myelin-associated glycoprotein (MAG)²⁸ to identify oligodendrocytes. Primary antibodies were visualized using Cy3-conjugated goat anti-mouse or goat anti-rabbit antibodies (Dianova, Hamburg, Germany).

Intraretinal Transplantation of Neural Precursor Cells
Cells were centrifuged, resuspended in Hanks’ balanced salt solution (60,000 cells/µl), and placed on ice until transplantation. The ß2/ß1 knock-in mutants and age-matched wild-type mice were deeply anesthetized, a glass micropipette was inserted into the vitreous of the right eye, and approximately 1.5 µl of vitreous fluid was removed. Subsequently, the same volume of a cell suspension was injected. Intraretinal transplantation was achieved by gently lesioning the retina with the micropipette simultaneously with the injection of cells.^{19 29} Before each injection, cells were triturated to maintain a single-cell suspension.

Determination of the Number of Donor-Derived Cells in Host Retinas
Four weeks after transplantation, animals were deeply anesthetized and fixed by perfusion with 4% PA in PBS. Eyes were quickly removed and serially sectioned with a thickness of 40 µm using a vibratome. Donor-derived cells in host retinas were identified by their EGFP fluorescence, the number of integrated cells in each retinal layer was determined, and the total number of donor-derived cells per host retina was calculated. Six animals from each genotype were analyzed. Statistical analyses of data were performed using the Mann-Whitney test.

Immunohistochemical Analysis of Host Tissue
Immunohistochemistry was performed to identify donor-derived neural cell types in the host tissue. To minimize bleaching of the EGFP fluorescence of donor cells during qualitative analysis of the tissue, we enhanced the endogenous EGFP signal by incubating the sections with polyclonal chicken antibodies to green fluorescent protein (Chemicon, Temecula, CA). Sections were simultaneously incubated with one of the following cell type–specific antibodies: monoclonal mouse antibodies to GFAP to visualize astrocytes, monoclonal mouse antibodies to MAG to visualize oligodendrocytes, and monoclonal mouse antibodies to ß-tubulin type III or neurofilament (Roche Diagnostics, Mannheim, Germany) or polyclonal rabbit antibodies to protein gene product 9.5 (PGP 9.5; Biotrend, Köln, Germany) to visualize nerve cells. Primary antibodies were detected with Cy2-conjugated anti-chicken and Cy3-conjugated anti-mouse or anti-rabbit antibodies (Dianova). Analysis of sections was performed with a laser confocal microscope (LSM-510; Carl Zeiss, Oberkochen, Germany).

Neural precursors were also transplanted into the retina of 2-month-old wild-type mice. Retinas of these animals were analyzed for the presence of donor-derived oligodendrocytes and myelin 6 months after transplantation. Animals were perfusion-fixed, and the eyes were quickly removed, opened, and incubated with MAG antibodies for 24 hours at 4°C. Cy3-conjugated anti-mouse antibodies were used to visualize the primary antibodies. Retinas were flatmounted and examined with a fluorescence microscope (Axiophot; Zeiss).

Light and Electron Microscopy
Untreated ß2/ß1 knock-in mutants (7-month-old) and age-matched wild-type mice were used to analyze the histology of the retina by light microscopy. Animals were perfusion fixed with PBS containing 4% PA and 3% glutaraldehyde. Eyes were immediately opened and stored in the same fixative for at least 12 hours. Tissue was immersed in 2% OsO₄ for 2 hours, dehydrated in an ascending series of methanol, and embedded in Epon resin. Semithin sections were prepared from central regions of the retina and stained with methylene and toluidine blue.

Retinas from wild-type mice were prepared 6 months after transplantation to study donor-derived myelin at the light and electron microscopic levels. Small pieces of retinas with heavily myelinated nerve fiber layers were selected, immersed in 2% OsO₄, and embedded in Epon resin. Semithin sections were stained with methylene and toluidine blue. Ultrathin sections were counterstained with lead citrate and analyzed with an electron microscope (EM 10C; Zeiss).

	Results

Top Abstract Introduction Methods Results Discussion References

 
Retina of Adult ß2/ß1 Knock-in Mutants
Spinal precursor cells were transplanted into the retina of 6-month-old wild-type mice and age-matched ß2/ß1 knock-in mutants, and host tissue was analyzed 1 month later. To obtain more information about the phenotype of ß2/ß1 knock-in retinas at the time of analysis, we performed light microscopy and GFAP immunohistochemistry on untreated mutant and wild-type retinas from 7-month-old animals. At this age, the thickness of the outer nuclear layer of ß2/ß1 knock-in retinas was significantly reduced when compared with wild-type retinas (compare Figs. 1a and 1b ). Moreover, inner and outer segments of mutant photoreceptor cells (Fig. 1b) were significantly shorter than those of wild-type cells (Fig. 1a) . Apoptotic photoreceptor cells were frequently observed in adult ß2/ß1 knock-in retinas, but were virtually absent from age-matched wild-type retinas (not shown).²³ Degeneration of photoreceptor cells in ß2/ß1 knock-in mutants correlated with elevated levels of GFAP immunoreactivity in retinal astrocytes and intense GFAP positivity of Müller cell processes (compare Figs. 2a and 2b ). Neural precursor cells were thus transplanted into a pathologically altered adult retina, characterized by the apoptotic death of photoreceptor cells and reactive astrogliosis.

View larger version (70K): [in this window] [in a new window]   Figure 1. Histology of the retina of 7-month-old wild-type mice and age-matched ß2/ß1 knock-in mutants. The outer nuclear layer of the mutant retina showed less thickness (b) when compared with the wild type (a). ß2/ß1 knock-in photoreceptor cells showed short inner and outer segments (b, ). Sections from both genotypes were prepared from central regions of the retina. inl, inner nuclear layer; onl, outer nuclear layer. Bar, 25 µm.

View larger version (66K): [in this window] [in a new window]   Figure 2. Expression of GFAP in adult wild-type and ß2/ß1 knock-in retinas. Expression of GFAP in the wild-type retina was restricted to astrocytes located at the vitread margin of the retina (a). In mutant retina (b), expression of GFAP was elevated in retinal astrocytes. In addition, Müller cell processes were GFAP-immunoreactive in mutant (b), but not in wild-type (a), retinas. Bar, 50 µm.

Number of Donor-Derived Cells in Adult Host Retinas
Donor cells in host retinas of both genotypes were readily identified by their expression of EGFP (Figs. 3a 3c) . In wild-type (Fig. 3a) and ß2/ß1 knock-in (Fig. 3c) retinas, grafted cells integrated into the host tissue without obviously disrupting the retinal histoarchitecture (Figs. 3b 3d) , and differentiated into a variety of morphologically distinct cell types. Virtually all these cells adopted a complex cytoarchitecture and extended several processes into the host retina of both genotypes (Fig. 3) . In wild-type retinas, donor-derived cells were usually located in the innermost retinal layers (i.e., nerve fiber, ganglion cell, and inner plexiform layers; Fig. 3a ). In mutant retinas, in comparison, EGFP-positive cells were frequently found also in deeper retinal layers (i.e., inner nuclear, outer plexiform, and outer nuclear layers; Fig. 3c ). Together, transplanted spinal precursors integrated in a nondisruptive manner, differentiated into morphologically complex cell types, and survived for considerable periods (i.e., up to 6 months, see description later) in adult retinas of both genotypes.

View larger version (69K): [in this window] [in a new window]   Figure 3. The distribution of donor-derived cells in the retinas of adult wild-type mice (a) and ß2/ß1 knock-in mutants (c) 1 month after transplantation of spinal precursor cells. In the wild-type (a), a layer of EGFP-positive, donor-derived cells was attached to the inner limiting membrane. Several EGFP-positive cells were located in the inner plexiform layer (ipl) and extended a complex network of processes within this layer (a). The cell body of one donor cell (arrowhead in a) was located in the inner nuclear layer (inl). Donor-derived cells in the retina of a ß2/ß1 knock-in mutant (c) also revealed a complex cytoarchitecture and extended numerous processes throughout the host retina. Several cells were located in the inner plexiform layer. EGFP-positive cells in mutant retinas were also located in the inner nuclear layer and at the interface between the inner nuclear layer and outer nuclear layer (onl, c). (b, d) Phase-contrast images of (a) and (c), respectively. Bar, 50 µm.

View larger version (31K): [in this window] [in a new window]   Figure 4. The number of donor-derived cells in adult retinas of wild-type and ß2/ß1 knock-in mice 1 month after transplantation of spinal precursors. Retinas of ß2/ß1 knock-in mutants (a, black bar) contained significantly more EGFP-positive cells than retinas of age-matched wild-type mice (a, hatched bar). Analysis of individual retinal layers (b) revealed similar numbers of EGFP-positive cells in the nerve fiber-ganglion cell layer (gcl) and inner plexiform layer (ipl) of both genotypes. In contrast, numbers of donor-derived cells in the inner nuclear layer (inl) and outer plexiform layer (opl) were significantly higher in mutant retinas than in wild-type hosts. In the outer nuclear layer (onl), EGFP-positive cells were found in ß2/ß1 knock-in mutants, but not in wild-type mice. Bars represent the mean value (±SEM) of six animals. *P < 0.05; **P < 0.01, according to the Mann-Whitney test.

Retinal astrocytes located at the vitread margin of the retina were the only GFAP-positive cells in untreated wild-type retinas (Fig. 2a) . In untreated ß2/ß1 knock-in retinas, GFAP-immunoreactivity was additionally detectable in Müller cell processes (Fig. 2b) . However, when wild-type or mutant retinas were analyzed 1 month after transplantation of neural precursors, GFAP-positive cells were detectable also in other retinal layers, and were particularly numerous in the inner plexiform layer (for a wild-type retina, see Figs. 5b and 5f ). Comparison of EGFP and GFAP immunoreactivity revealed coexpression of both proteins in many if not all of these unusually positioned GFAP-positive cells and thus unequivocally identified them as donor-derived astrocytes (compare Figs. 5a and 5b or 5e and 5f; see Figs. 5c and 5g ). Donor-derived astrocytes (i.e., cells positive for EGFP and GFAP) were also detected in the nerve fiber and ganglion cell layers of wild-type and mutant mice (Figs. 5a 5b 5c and not shown).

View larger version (103K): [in this window] [in a new window]   Figure 5. Identification of donor-derived astrocytes 1 month after transplantation of spinal precursor cells into the retina of adult wild-type mice. The majority of EGFP-positive, donor-derived cells in a wild-type retina were located in the inner plexiform layer (ipl) and elaborated a dense network of processes (a). Immunostaining with GFAP antibodies (b) identified several of these donor-derived cells as astrocytes (arrowheads in a, b). Overlay of the EGFP and GFAP images demonstrates colocalization of both proteins in several cells (c). An EGFP-positive (a, arrow) but GFAP-negative (b) cell is shown in the inner nuclear layer (inl) of the host retina. An EGFP- (e) and GFAP-positive (f) astrocyte in the inner plexiform layer of a wild-type mouse. (g) Merged image of (e) and (f). (d, h) Phase-contrast images of (a–c) and (e–g), respectively. Bar, 25 µm.

View larger version (86K): [in this window] [in a new window]   Figure 6. Identification of donor-derived oligodendrocytes 1 month after transplantation of spinal precursors into the retina of adult wild-type and ß2/ß1 knock-in mice. Numerous EGFP-immunoreactive cells were located in the inner plexiform layer (ipl) of a wild-type retina (a). Their processes were mainly restricted to this layer, but some donor cells also extended processes into the inner nuclear layer. One EGFP-positive cell (a, arrowhead), located with its cell body at the upper margin of the inner plexiform layer, extended processes toward the nerve fiber layer. The processes appeared to terminate on fascicles of ganglion cell axons (a). A second EGFP-positive cell, located in proximity with the first, also extended processes toward the nerve fiber layer (a, arrow). Immunostaining of the tissue with MAG antibodies revealed intense immunoreactivity in association with axon fascicles (b, arrows) in the nerve fiber layer. (c) Merged image of (a) and (b), confirming termination of EGFP-positive processes on MAG-immunoreactive fascicles. EGFP-positive cells (e), located in the inner plexiform layer and terminating with their processes on MAG-immunoreactive fascicles in the nerve fiber layer (f), were also present in the retina of ß2/ß1 knock-in mutants. (g) Merged image of (e) and (f). (d, h) Phase-contrast images of (a–c) and (e–g), respectively. Bar, 25 µm.

View larger version (51K): [in this window] [in a new window]   Figure 7. Localization of EGFP- and MAG-immunoreactivity in a flatmounted wild-type retina 6 months after transplantation of spinal precursor cells. Numerous EGFP-positive cell bodies were located at the vitread side of the retina, and faint EGFP immunoreactivity was associated with fascicles of ganglion cell axons (a). Colocalization of EGFP positivity with intense MAG immunoreactivity in axon fascicles (b) indicated myelination of large areas of the host nerve fiber layer by donor-derived oligodendrocytes. Bar, 100 µm.

View larger version (71K): [in this window] [in a new window]   Figure 8. Myelinated ganglion cell axons in a wild-type retina 6 months after transplantation of spinal precursors. Several myelinated axon fascicles (a, arrowheads) were present in the nerve fiber layer (a), with a high number of myelin sheaths in each axon fascicle (b). Bar, (a) 50 µm; (b) 25 µm.

View larger version (63K): [in this window] [in a new window]   Figure 9. Localization of PGP 9.5 immunoreactivity in a ß2/ß1 knock-in retina 1 month after transplantation of spinal precursors. Donor-derived cells were situated in the inner plexiform layer (ipl) and inner margin of the outer nuclear layer (onl, arrows in a). One of these cells (uppermost cell in a) extended processes into the outer plexiform layer of the host retina. Expression of PGP 9.5 was restricted to horizontal, amacrine, and ganglion cells in the host tissue (b). A comparison of (a) and (b) demonstrates PGP 9.5 negativity (arrows in b) of all donor-derived cells. (c) Phase contrast image of (a) and (b). inl, inner nuclear layer. Bar, 25 µm.

	Discussion

Top Abstract Introduction Methods Results Discussion References

Quantitative analysis of recipient tissues revealed a significantly increased number and a more widespread distribution of donor cells in ß2/ß1 knock-in retinas than in wild-type retinas. An obvious assumption is that cellular and molecular differences between wild-type and mutant retinas account for the more pronounced integration of grafted cells into ß2/ß1 knock-in retinas. For instance, it has recently been demonstrated that intravitreally grafted hippocampal precursor cells integrate into the dystrophic retina of adult rats, whereas integration into wild-type retinas requires mechanical lesioning of the retina.³⁰ It has been suggested that the improved accessibility of the mutant retina may be related to alterations of Müller cells that enable grafted cells to cross the inner limiting membrane and infiltrate the retina.³⁰ Elevated levels of cell recognition molecules (Bartsch et al., unpublished observations, 2001) or trophic factors^{31 32 33} in pathologically altered retinas may also explain the improved integration and increased numbers of grafted precursors, in that these molecules may stimulate migration and/or proliferation or may support survival of donor cells.

The total number of donor cells in host retinas was low compared with the number of cells used in our transplantation experiments. Because we found no evidence for immunologic rejection or degeneration of grafted cells, we conclude that only a limited number of cells gained access to the host retina at the time of transplantation. In fact, we found numerous EGFP-positive cells in the vitreous of both genotypes, with many donor cells being attached to the inner surface of the recipient retina. It is interesting in the present context that myelination of the nerve fiber layer of recipient retinas was limited 1 month after transplantation but was extensive 6 months after transplantation (see later discussion). This finding also argues against extensive degeneration of donor cells, but instead demonstrates long-term survival of grafted cells in adult host retinas. Moreover, it is indicative of continuous proliferation, migration, and neural differentiation of grafted precursors within the recipient tissue.

Analysis of recipient wild-type and mutant retinas with EGFP and GFAP antibodies 1 month after transplantation revealed that a large fraction of grafted precursor cells had differentiated into astrocytes. Donor-derived astrocytes were located in the nerve fiber and ganglion cell layers, the normal positions of retinal astrocytes.³⁴ However, they were also detectable in retinal layers not normally populated by retinal astrocytes. Ectopically positioned donor-derived astrocytes were particularly numerous in the inner plexiform layer. In a previous study, we have transplanted spinal and striatal precursors into the retina of young postnatal wild-type mice. Different from adult hosts, donor-derived astrocytes in these young recipients were preferentially positioned in the nerve fiber and ganglion cell layer.¹⁹ Young host retinas thus appear to differ from adult host retinas in expressing cues that instruct differentiation of multipotent cells into appropriate cell types in appropriate locations.

Neural precursors grafted into the retina of adult wild-type and mutant mice also differentiated into oligodendrocytes, a cell type not normally present in the mouse retina. Electron microscopic analysis revealed that donor-derived oligodendrocytes had formed ultrastructurally intact myelin sheaths around ganglion cell axons. These findings confirm the view that the normally nonmyelinated intraretinal segments of ganglion cell axons are, in principle, competent to become myelinated once myelin-forming glial cells have access to the retinal nerve fiber layer.^{19 29} They thus support the hypothesis that nonneuronal factors yet to be identified at the lamina cribrosa prevent migration of oligodendrocyte progenitor cells from the optic nerve into the retina, and, as a consequence, myelin formation within the retina.^{19 29 35 36 37 38}

We have recently grafted spinal and striatal precursors into the retina of young postnatal wild-type mice and observed differentiation of a significant fraction of donor cells into oligodendrocytes.¹⁹ One month after transplantation, a considerable portion of the host nerve fiber layer was myelinated by donor-derived oligodendrocytes. After 4 months, virtually the entire nerve fiber layer was myelinated, demonstrating progressive myelination of the host tissue over extended periods.¹⁹ In the current study, we used adult hosts and, compared with young postnatal recipients, observed significantly fewer oligodendrocytes and myelin sheaths 1 month after transplantation of spinal precursor cells. However, large areas of the nerve fiber layer were myelinated 6 months after transplantation, demonstrating progressive and ultimately extensive intraretinal myelination also in adult recipients. It thus appears that the nerve fiber layer of adult hosts becomes as extensively myelinated as the nerve fiber layer of young postnatal hosts, although myelination proceeds more slowly in adult than in young recipients. These observations are in line with a recent study demonstrating that remyelination of experimentally demyelinated axons in the aged adult CNS occurs as extensively as in the young adult CNS, but at a significantly slower rate.³⁹

Evidence for differentiation of grafted precursors into nerve cells was not obtained. Double-immunolabeling experiments using antibodies to EGFP and neuronal antigens (i.e., ß-tubulin type III, neurofilament, or PGP 9.5), all failed to identify donor-derived neurons in wild-type and mutant retinas. However, a few EGFP-positive donor cells did not express GFAP and did not correspond to oligodendrocytes, as judged from their location and cytoarchitecture. For instance, some EGFP-positive and GFAP-negative cells were located in the outer nuclear layer and extended horizontally oriented processes into the outer plexiform layer. Although the identity of these few cells remains unknown, they may correspond to immature cells that had not yet expressed markers for mature glial cells and/or to donor-derived nerve cells that escaped identification with the neuronal markers used in this study.

Exclusive or preferential differentiation of multipotent precursors into astrocytes or oligodendrocytes may be expected in a non-neurogenic CNS region characterized by a prominent reactive astrogliosis and the presence of nonmyelinated axons. However, fundamentally different results have been obtained with adult hippocampal precursors that were grafted into the dystrophic retina of adult Royal College of Surgeons (RCS) rats³⁰ or into the mechanically lesioned retina of adult wild-type rats.⁴⁰ Exclusive differentiation of hippocampal precursors into nerve cells was observed in the RCS retina,³⁰ whereas differentiation into neurons and astrocytes was observed in the mechanically lesioned wild-type retina.⁴⁰ Evidence for the presence of significant numbers of donor-derived oligodendrocytes was not reported in either of these studies. The reasons for the different fate of embryonic spinal versus adult hippocampal precursors in adult retinas are presently unknown. It is possible that the different fate of spinal and hippocampal precursors is related to the use of different species (mice versus rats) as a host. It is also possible that the different phenotypes of recipient retinas account for the different fate of both precursor populations. However, it should be noted that preferential neuronal differentiation of hippocampal precursors occurs in such diverse recipient tissues as the dystrophic retina of RCS rats and the mechanically lesioned retina of wild-type rats. Furthermore, exclusive differentiation of spinal precursors into glial cells and preferential differentiation of hippocampal precursors into nerve cells was observed, not only in mutant mice and rats, but also in wild-type mice (the present study) and rats,⁴⁰ respectively. It is therefore tempting to speculate that differences between the two precursor populations, either intrinsic or related to different culture conditions, account for the divergent fate of spinal and hippocampal precursors. For example, hippocampal precursors were expanded using FGF-2,^{30 40} whereas spinal precursors were expanded in the presence of FGF-2 and EGF (the present study). There is evidence for the presence of distinct EGF- and FGF-2-dependent neural precursor populations. Furthermore, it has been demonstrated that EGF, compared with FGF-2, favors glial differentiation of neural precursors, both in vitro and in vivo.^{41 42 43 44 45 46}

The present and other studies^{30 40} demonstrate robust integration, long-term survival, and neural differentiation of heterotopically transplanted neural precursor cells in the normal and pathologically altered adult retina. However, differentiation of heterotopically grafted precursors into retina-specific cell types was not observed in any of these studies. The recent isolation, cultivation, and characterization of retinal precursor cells from the adult eye of various mammalian species, including humans, is therefore of particular interest.⁴⁷ Retinal precursor cells are pigmented cells located in low numbers at the ciliary margin. They display the two cardinal features of stem cells: multipotentiality and the capacity for self-renewal. When retinal precursor cells are induced to differentiate in vitro, they give rise to cells expressing antigens characteristic of Müller cells, bipolar neurons, and rod photoreceptor cells.⁴⁷ Retinal precursor cells have also been isolated from adult rats.⁴⁸ It is now of obvious interest to obtain information about the fate of grafted retinal precursor cells in the normal and dystrophic adult retina.

	Acknowledgements

 
The authors thank Stephan Linke and Klaus Rüther for critical reading of the manuscript, Vladimir Sytnyk for help with the laser scanning microscope, and Masaru Okabe for EGFP transgenic mice.

	Footnotes

 
Submitted for publication March 30, 2001; revised July 20, 2001; accepted September 5, 2001.

Commercial relationships policy: N.

The publication costs of this article were defrayed in part by page charge payment. This article must therefore be marked "advertisement" in accordance with 18 U.S.C. 1734 solely to indicate this fact.

Corresponding author: Udo Bartsch, Zentrum für Molekulare Neurobiologie, Universität Hamburg, Martinistr. 52, 20246 Hamburg, Germany. udo.bartsch{at}zmnh.uni-hamburg.de

	References

Top Abstract Introduction Methods Results Discussion References

 

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