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The Journal of Neuroscience, April 15, 2003, 23(8):3112
BRIEF COMMUNICATION
Inactivation of Myelin-Associated Glycoprotein Enhances Optic Nerve RegenerationEric V. Wong1, 3, Samuel David2, Michele H. Jacob1, and Daniel G. Jay1 1 Departments of Physiology and Neuroscience, Tufts University Medical School, Boston, Massachusetts 02111, 2 Center for Research in Neuroscience, Montreal General Hospital Research Institute and McGill University, Montreal, Quebec, Canada, and 3 Department of Biology, University of Louisville, Louisville Kentucky 40292
ABSTRACT
TOP
ABSTRACT
Introduction
CNS regeneration in higher vertebrates is a long sought after goal in neuroscience. The lack of regeneration is attributable in part to inhibitory factors found in myelin (Caroni and Schwab, 1988a
). Myelin-associated glycoprotein (MAG) is an abundant myelin protein that inhibits neurite outgrowth in vitro (McKerracher et al., 1994
Key words: MAG; CALI; optic nerve explants; nerve regeneration; retinal neurons; myelin
Introduction
Long-distance axonal regeneration in the CNS does not occur in adults of higher order vertebrates. This is thought to be attributable to a reduced intrinsic ability of adult neurons to sprout neurites and to inhibition by the environment, particularly the CNS myelin. CNS (but not PNS) myelin inhibits nerve regeneration (Caroni and Schwab, 1988a
MAG is a ~100 kDa transmembrane glycoprotein abundantly found in CNS myelin comprising ~1% of total myelin protein (Quarles et al., 1973
/
Materials and Methods
Retinal strip cultures. Embryonic day 7 (E7) chick retinas were dissected away from the pigment epithelium and other tissue, flattened onto nitrocellulose filters, and cut into 400 µm strips as described previously (Halfter et al., 1983
CALI of MAG/myelin in solution. For CALI treatment, myelin or MAG [both prepared as described previously (McKerracher et al., 1994
Retina-optic nerve organ culture. E15 retinas were explanted with attached optic nerve and tracts and given a crush injury with cold forceps halfway between the retina and the chiasm. Five microliters of MG-labeled antibody (2 mg/ml in HBSS) were injected into the optic nerve with a Hamilton syringe both proximal and distal to the lesion. These explants were incubated with MG-3E4 or MG-anti-PLP for 2 hr at 37°C, 6% CO2, in the retina medium described in above, plus BDNF (2 ng/ml) for trophic support of the older explants (Rodriguez-Tebar et al., 1989
CALI of MAG in explants. Retinas were cultured with their optic nerves still attached and extending to the optic chiasm. The optic nerves were injected with 5 ml of either MG-3E4 or MG-anti-PLP (as a negative control). The optic nerve was then crushed with fine forceps midway between the retina and optic chiasm and incubated for 2 hr at 37°C to allow the antibody to penetrate the tissue and bind. The optic nerve was laser irradiated within a 2-mm-diameter spot at the crush site. The explants were examined 36 hr after CALI treatment. Enhanced axonal regeneration was demonstrated by anterograde DiI labeling of optic nerve fibers and by retrograde labeling of RGC cell bodies by DiI or FITC-dextran at the distal optic nerve stump.
Light and electron microscopy. The presence of regenerated axons in the crush site after anti-MAG and anti-PLP antibody incubation and CALI was determined by light and electron microscopic analysis. Test and control optic nerves were fixed by immersion in 2% glutaraldehyde and freshly prepared 2% paraformaldehyde in Dulbecco's PBS, pH 7.4, for 3 hr at room temperature followed by the same fix overnight at 4°C. The tissue was rinsed once in PBS and then postfixed for 2 hr at room temperature in 1% osmium tetroxide reduced with 1% potassium ferricyanide in 0.1 M sodium cacodylate buffer containing 5% sucrose. The tissue was then rinsed briefly in distilled water, dehydrated in a graded series of ethanols, and embedded in Embed 812 (Jacob et al., 1986
Chondroitin sulfate proteoglycan immunohistochemistry. Optic nerves were fixed in 4% paraformaldehyde in 100 mM phosphate buffer and gradually equilibrated to 30% sucrose. The nerves were embedded and frozen in Tissue-Tek and cut into 15 µm sections on a cryostat. Chondroitin sulfate proteoglycan (CSPG) immunohistochemistry was performed with antibody 9BA12 (a generous gift from W. Halfter, University of Pittsburgh) and Alexa-Fluor-conjugated secondary antibody (Molecular Probes) by epifluorescence with a Nikon T200 microscope and a Micromax YHS-1300 CCD camera.
Results
We investigated the contribution of MAG to the inhibitory properties of myelin in axon regeneration in the CNS. To do this, we acutely inactivated MAG in CNS myelin using CALI (Jay, 1988
For CALI of MAG, we used a monoclonal antibody, INM2C4.3E4 (3E4), which recognizes an extracellular epitope of MAG (data not shown). 3E4 was generated against bovine myelin and cross-reacts specifically with MAG in chick CNS myelin preparations (Fig. 1A). We tested CALI of MAG on E7 chick retinal explants grown on fibronectin because we observed that MAG caused ~80% of the RGC growth cones to collapse for explants grown on fibronectin but not on laminin, in agreement with published studies (David et al., 1995
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Figure 1. Retinal ganglion cell growth cones collapse in response to CNS myelin or recombinant MAG. A, Western blot of chick brain myelin with 3E4. Lane 1 is a no primary antibody control; lane 2 is probed with the 3E4 antibody and displays a prominent band of MAG at 110 kDa. B, An RGC growth cone on fibronectin is shown collapsing in response to MAG (0.5 mg/ml). C, MAG inactivated by CALI does not cause growth cone collapse. D, Retinal explants grown on bronectin were assayed with MAG (MAG), MAG inactivated by CALI (antiMAG), MAG treated with 3E4 but without laser (antiMAG,CALI), myelin treated with 3E4 without laser (Myl antiMAG), myelin treated with CALI against MAG(Myl antiMAG,CALI), and myelin treated with CALI against myelin proteolipid protein (Myl antiPLP, CALI). Error bars reflect SE. CALI of MAG and control treatment results are significantly different as measured by unpaired t test (p < 0.0001).
We applied CALI of MAG to regions of nerve crush in E15 chick optic nerve organotypic cultures to address the in situ role of MAG in regeneration. At E15, optic nerve myelination in chick has just begun, and MAG-immunoreactive oligodendrocytes can be observed throughout the optic tract (data not shown). Retinas were cultured with their optic nerves still attached and extending to the optic chiasm. These explants were injected with either MG-3E4 or MG-anti-PLP (as a negative control) immediately before the optic nerve was crushed midway between the retina and optic chiasm. After a 2 hr incubation at 37°C to allow antibodies to penetrate the tissue and bind MAG or PLP, the optic nerve was laser irradiated within a 2 mm spot at the crush site. The laser spot did not encompass the entire nerve; rather, it left ~1-2 mm on either side of the spot untreated. Axonal regeneration was assessed by anterograde labeling from the retina with DiI. In CALI of PLP-treated explants, we did not observe labeled axons along the optic nerve, despite bright fluorescence seen in the retina (Fig. 2, left panels). In contrast, fluorescent axons were observed throughout the optic nerve beyond the crush site in the CALI of MAG-treated tissue (Fig. 2, right panels). Regenerating axons in the MAG-inactivated explants grew to the end of the explant within 36 hr. This growth was at least 2 mm beyond the crush site and was the farthest extent possible in these experiments. Ultrastructural photomicrographs (Fig. 3A-C) also show that fibers extend across the lesion site in the CALI of MAG-treated optic nerve (Fig. 3C) but not across the crush site in the CALI of PLP control (Fig. 3B). Electron microscopy of the site of nerve crush in the CALI of MAG-treated optic nerve shows many intact regenerating axons (Fig. 3D). Furthermore, CALI of MAG did not significantly alter the expression of at least one other inhibitory molecule found in the chick optic nerve, chondroitin sulfate proteoglycan (Fig. 3E,F). The spotty staining pattern seen in both control and CALI of MAG-treated optic nerve is expected, because myelination is only in initial stages at this age. Together, these findings support the hypothesis that the direct localized loss of MAG function allows for significant axon regrowth across a site of nerve crush.
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Figure 2. CALI of MAG enhances regeneration in E15 optic nerve. E15 retinas were explanted with attached optic nerve and tracts and given a crush injury with cold forceps halfway between the retina and chiasm. The axons were anterograde labeled with DiI crystals placed in the retina >0.5 mm from the optic fissure. As the explant was incubated for 3 d, the dye was transported up axons, and in the case of CALI-MAG (right panels), these axons could be seen beyond the point of lesion. In contrast, the control explant treated with CALI-PLP (left panels) showed no axon labeling beyond the lesion. Scale bar, 20 µm.
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Figure 3. Histology of crush site. Light and electron micrographs demonstrating the histological appearance of the optic nerve crush site in test and control conditions. A, Control optic nerve shows the normal intact axons. B, Crushed optic nerve treated with anti-PLP antibody and CALI shows the site of damage and absence of axons that cross the gap. C, Crushed optic nerve treated with anti-MAG antibody and CALI shows the site of the crush that is now occupied mostly by regenerated axon processes, with only small regions of damage remaining. Scale bar, 24 µm. Black side bars show the site of nerve crush in B and C. Thin unmyelinated regenerating axons were confirmed at part of this site of nerve crush (marked by black box in C) after CALI of MAG using electron microscopy (D). Magnification, 34,000×. Scale bar, 0.14 µm. CSPG immunohistochemistry of the optic nerve crush site in anti-PLP-treated (E) and anti-MAG-treated (F) tissue shows no differences between the two treatments. Scale bar, 30 µm.
We quantified the extent of axonal regeneration by placing DiI crystals at the cut end of the optic nerve 36 hr after CALI and assessing fluorescent labeling in the retina. The fluorescently labeled RGC soma in the retina were counted 24 hr later (n > 10 retinas for each experimental treatment). Figure 4A shows retrogradely labeled retinal cells of E15 retina-optic nerve explants immediately after removal from the embryo, without crush or CALI treatment (98 ± 13 soma per square millimeter). When retrograde labeling was performed after a crush lesion, fluorescent cells or axons in the retina were never observed (Fig. 4B), reflecting the lack of regenerated fibers distal to the site of lesion. In contrast, CALI of MAG resulted in marked retinal axon regeneration as measured by the number of fluorescent cell bodies (89 ± 16 soma per square millimeter) (Fig. 4D). None of the control treatments promoted regeneration. CALI directed against PLP had no effect on regeneration because no labeled retinal cells were seen (Fig. 4C). Similarly, neither laser irradiation alone nor MG-3E4 antibody without irradiation promoted regeneration into the E15 optic nerve. Our findings are summarized in Figure 4E. These observations demonstrate a significant inhibitory role for MAG in optic nerve growth in situ and that inactivation of MAG in a myelinated CNS nerve allows axon regeneration into this previously inhibitory environment.
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Figure 4. CALI of MAG permits regeneration of myelinated optic nerve. E15 retinas from retina-optic nerve explants retrogradely labeled with DiO are shown. Representative fields are shown for E15 no crush (A), E15 crush (B), E15 with PLP inactivation (C), and E15 with MAG inactivation (D). Scale bar, 10 µm. E, Quantification of the retrograde-labeled soma was performed in the three brightest 0.2 mm2 camera fields per retina (n = 10), and the average label density and SE are given for each condition. Pictures were taken at identical brightness/contrast settings on a Zeiss confocal microscope. no Ab, No antibody.
Discussion
Our findings establish that MAG is a prominent contributor to the inhibition of CNS nerve regeneration in situ. We used an organotypic culture system that models regeneration of the optic nerve after crush injury. Under normal culture conditions, neither anterograde nor retrograde labeling can detect axons that cross the lesion. However, after specific inactivation of MAG, axons are clearly seen crossing the crush site, and retrograde labeling from the nerve stump labels retinal soma to the same extent seen with explants that were not crushed. The lack of regeneration after CALI of PLP, another abundant myelin protein, argues against nonspecific damage to myelin as a cause of the observed regeneration. Although it is possible that CALI could inactivate neighboring proteins that may be inhibitory, our previous work has shown a high degree of spatial restriction of CALI-mediated damage, even within a multi-subunit membrane protein in situ (Liao et al., 1995
Although in vitro studies have implicated MAG as an inhibitor of neurite outgrowth (McKerracher et al., 1994
It is curious that CALI of MAG allowed significant regrowth of axons through CNS myelin despite the presence of other inhibitory activities (such as Nogo). Our findings do not discount the importance of other inhibitory factors in the myelin that may also act on the neurons. Indeed, chromatographic separation of myelin proteins has revealed several fractions with outgrowth inhibitory activity (McKerracher et al., 1994
Many studies using the IN-I blocking antibody have demonstrated the role of Nogo in preventing regeneration (Schnell and Schwab, 1990
FOOTNOTES Received Feb. 1, 2002; revised Jan. 15, 2003; accepted Jan. 24, 2003.
This work was supported by grants from the American Paralysis Association to D.G.J. and the National Institutes of Health to D.G.J. (EY11992 and NS34669) and M.H.J. (NS21725) and a National Research Service Award to E.V.W. We thank Russell McConnell, Catherine Linsenmayer, and the Tufts Vision Research Center for expert assistance with electron microscopy. We also thank Julie Kerner and Takashi Sakurai for helpful discussion and critical reading of this manuscript.
Correspondence should be addressed to Dr. Daniel G. Jay, Department of Physiology, Tufts University Medical School, 136 Harrison Avenue, MV709, Boston, MA 02111. E-mail: daniel.jay{at}tufts.edu.
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