Responses of Regenerating Rat Retinal Ganglion Cell Axons to Contacts with Central Nervous Myelin in vitro (original) (raw)
Related papers
The Journal of Comparative Neurology, 1990
It has been postulated that myelin degradation products may inhibit regrowth of mammalian central axons and that central nervous system (CNS) myelin and oligodendrocytes may constitute a "nonpermissive substrate" for axonal growth. To address these issues, we utilized an X-linked rat mutant, myelin-deficient or md. In the optic nerve of this mutant, 40 days and more postnatally, normal myelin is absent and oligodendrocytes are few (Dentinger et al. Brain Res. 344:255-266,1985). Twenty-eight days before sacrifice, we operated on four groups of 50-day-old md rats and age-matched normal littermates according to the following protocols: I) unilateral intraorbital optic nerve crush; 2) beginning within 1 hour of nerve crush, daily intraperitoneal injection of GM1 ganglioside (20 mg/kg) dissolved in phosphate-buffered saline (PBS); 3) daily intraperitoneal injection of PBS alone, also begun within 1 hour of nerve crush; 4) severance of the optic nerve immediately behind the papilla 16 or 21 days after the primary crush lesions. Additionally, normal and md rats were killed 4 and 14 days after unilateral optic nerve injury. Nerves of unoperated md rats and their normal littermates were also processed. In the operated animals that did not receive GM1, ultrastructural analysis 4, 14, and 28 days after lesioning revealed that md optic nerves contained significantly greater numbers of regenerating axons, including growth cones and varicosities, than nerves of normal rats. Notably, 28 days postoperatively, (group I), regenerating axons were still abundant in md nerve, whereas, in nerves of normally myelinated littermates, axonal numbers were diminished markedly. Regenerating optic axons of both md and normally myelinated rats were oriented by linear astrocytic arrays and often were enclosed by astrocytic cytoplasm. In normal littermates, GM1 administration (group 2) induced a significant increase in the number of axons within the operative lesion. Paradoxically, GM1 inhibited the ordinarily robust regeneration of md axons. PBS-injected md and normal rats (group 3) showed no significant differences from noninjected, operated animals. Severance of the nerve at the papilla (group 4) 7-12 days before sacrifice confirmed the origination of axonal regrowth by retinal ganglion cells. The data provide in vivo support for a role of myelin breakdown products or the secretory products of oligodendroglia in the inhibition of regenerative axonal sprouting within mammalian CNS.
Investigative Ophthalmology & Visual Science, 2013
PURPOSE. In most mammalian species, retinal ganglion cell (RGC) axons are myelinated in the optic nerve, but remain nonmyelinated in the retinal nerve fiber layer and the most proximal (i.e., retina-near) region of the nerve. Here we analyzed whether RGCs are involved in the control of this characteristic distribution of oligodendrocytes and myelin in the primary visual pathway of mice.
Journal of Neurocytology, 1975
The proximal stump of a predominantly myelinated nerve (sternohyoid) was anastomosed in a tube to the distal stump of a largely unmyelinated nerve (cervical sympathetic) in order to explore the role of the axon in activating Schwann cells to produce myelin. The two nerves were examined after being united for periods between 3 and 15 weeks. At these times, regenerated myelinated and nonmyelinated fibres, originating from the proximal stump, were seen within the original fascicle in the distal stump of the sympathetic trunk. There was a significant (p < o.oi) increase in the mean number ofmyelinated fibres in the anastomosed sympathetic nerves from the mean number of myelinated fibres in the normal sympathetic nerve. The histological and ultrastructural features of the anastomosed nerves are described and the differences between the morphology of the intratubal and extratubal regions are highlighted. The results of this study may indicate that the axon instructs the Schwann cell to produce myelin, but before this conclusion is reached, the origin of the myelinating cells has to be determined.
Growth of injured rabbit optic axons within their degenerating optic nerve
The Journal of Comparative Neurology, 1990
Spontaneous growth of axons after injury is extremely limited in the mammalian central nervous system (CNS). It is now clear, however, that injured CNS axons can be induced to elongate when provided with a suitable environment. Thus injured CNS axons can elongate, but they do not do so unless their environment is altered.
Studies on the control of myelinogenesis. II. Evidence for neuronal regulation of myelin production
Brain Research, 1976
Tritiated thymidine has been used as a nuclear marker to trace the origin of Schwann cells, sited in the distal stump of a severed unmyelinated nerve, which are able to elaborate myelin around axons regenerating from an anastomosed proximal stump of a severed myelinated nerve. Two types of cross-anastomosis experiments were performed in young, adult rats: (1) the proximal stump of a myelinated sternohyoid nerve was labeled (5 mCi/kg body weight) selectively over a 4-day period of predetermined maximal thymidine uptake and two days later, after flushing the animal repeatedly with cold thymidine, the unmyelinated cervical sympathetic trunk was transected and its unlabeled distal stump linked to the proximal stump of the labeled sternohyoid nerve; (2) the distal stump of an unmyelinated cervical sympathetic trunk was labeled selectively over a 5-day period of predetermined maximal uptake and two days later, after flushing with cold thymidine, the myelinated sternohyoid nerve was severed and its unlabeled proximal stump linked to the labeled distal stump of the cervical sympathetic trunk. The fate of the labeled cells in each type of anastomosis was determined 3 weeks later by autoradiography and liquid scintillation spectrometry. In the first type, a small amount of label had migrated from proximal stumps but labeled Schwann cells were not found in successfully anastomosed distal stumps. In the second type, labeled Schwann cells were seen in the cervical sympathetic trunk in association with myelinated and non-myelinated axons regenerating from the sternohyoid nerve. These data suggest that the presence or absence of myelin formation by a Schwann cell is controlled by some property of the axon with which it is associated. Putative mechanisms underlying neuronal control of myelinogenesis are discussed.
Myelination of regenerated axons in goldfish optic nerve by Schwann cells
Journal of Neurocytology, 1992
This study uses immunohistochemistry and EM to examine the site of injury in goldfish optic nerve during axonai regeneration. Within seven days of nerve crush axons begin to regrow and a network of GFAP + reactive astrocytes appears in the nerve on either side of the injury. However, the damaged area remains GFAP-. By 42 days after nerve crush, the sheaths of new axons acquire myelin marker 6D2, and the crush area becomes populated by a mass of longitudinally-orientated Sq 00 + cells. Ultrastructurally, the predominant cells in the crush area bear a strong resemblance to peripheral nerve Schwann cells; they display a one-to-one association with myelinated axons, have a basal lamina and are surrounded by collagen fibres. It is proposed that these cells are Schwann cells which enter the optic nerve as a result of crush, where they become confined to the astrocyte-free crush area.
Experimental Neurology, 1998
We previously observed that the transient developmental suppression of myelination or disruption of mature myelin, by local intraspinal infusion of serum complement proteins along with a complement-fixing, myelin-specific antibody (e.g., anti-Galactocerebroside), facilitated avian brainstem-spinal axonal regeneration after spinal transection. We now report the effects of similar immunological protocols on axonal regeneration in the injured adult rat spinal cord. After a lateral hemisection injury of the T10 spinal cord, infusion of the above reagents, over 14 days at T11, facilitated the regeneration of some brainstem-spinal axons. The hemisection lesion enabled comparisons between the retrograde labeling within an injured brainstem-spinal nucleus and the uninjured contralateral homologue. The brainstem-spinal nucleus examined in detail was the red nucleus (RN), chosen for its relatively compact descending pathway within the dorsolateral cord. Comparing the number of labeled neurons within each RN, of an experimentally myelin suppressed animal, indicated that approximately 32% of injured rubrospinal projections had regenerated into the caudal lumbar cord. In contrast, controltreated animals (e.g., PBS vehicle alone, GalC antibody alone, or serum complement alone) showed little or no axonal regeneration. We also examined the ultrastructural appearance of the treated cords. We noted demyelination over 1-2 segments surrounding the infusion site (T11) and a further two segments of myelin disruption (delamination) on either side of the demyelinated zone. The demyelination is an active process (F3 days) with microglia and/or macrophages engulfing myelin. Thus, the facilitation of axonal regeneration through the transient suppression of CNS myelin may be fundamental to all higher vertebrates. 1998 Academic Press
Axon-glial relations during regeneration of axons in the adult rat anterior medullary velum
1998
The anterior medullary velum (AMV) of adult Wistar rats was lesioned in the midsagittal plane, transecting all decussating axons including those of the central projection of the IVth nerve. At selected times up to 200 days after transection, the degenerative and regenerative responses of axons and glia were analyzed using transmission and scanning electron microscopy and immunohistochemistry. In particular, both the capacity of oligodendrocytes to remyelinate regenerated fibers and the stability of the CNS/PNS junctional zone of the IVth nerve rootlet were documented. Transected central AMV axons exhibited four patterns of fiber regeneration in which fibers grew: rostrocaudally in the reactive paralesion neuropil (Group 1); randomly within the AMV (Group 2); into the ipsilateral IVth nerve rootlet, after turning at the lesion edge and growing recurrently through the old degenerated contralateral central trochlear nerve trajectory (Group 3); and ectopically through paralesion tears in the ependyma onto the surface of the IVth ventricle (Group 4). Group 1-3 axons regenerated unperturbed through degenerating central myelin, reactive astrocytes, oligodendrocytes, microglia, and large accumulations of hematogenous macrophages. Only Group 3 axons survived long term in significant numbers, and all became myelinated by oligodendrocytes, ultimately establishing thin sheaths with relatively normal nodal gaps and intersegmental myelin sheath lengths. Schwann cells at the CNS/PNS junction of the IVth nerve rootlet did not invade the CNS, but astrocyte processes grew across the junction into the PNS portion of the IVth nerve. The basal lamina of the junctional glia limitans remained stable throughout the experimental period.
Inactivation of Myelin-Associated Glycoprotein Enhances Optic Nerve Regeneration
The Journal of Neuroscience, 2003
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; Mukhopadhyay et al., 1994), but its role in regeneration remains controversial. To address this role, we performed nerve crush on embryonic day 15 chick retina-optic nerve explants and then acutely eliminated MAG function along the nerve using chromophore-assisted laser inactivation (CALI). CALI of MAG permitted significant regrowth of retinal axons past the site of lesion containing CNS myelin in contrast to various control treatments. Electron microscopy of the site of nerve crush shows abundant regenerating axons crossing the gap. When crushed optic nerve was retrogradely labeled at the nerve stump, no labeling of retinal neurons was observed. In contrast, labeling of CALI of MAG-treated crushed optic nerve showed significant retinal labeling (89 Ϯ 16 cells per square millimeter), a value indistinguishable from that seen with non-crushed nerve (98 Ϯ 13 cells per square millimeter). These findings implicate MAG as an important component of the myelin-derived inhibition of nerve regeneration. The acute loss of MAG function can promote significant axon growth across a site of CNS nerve damage.