Axonal regeneration of retinal ganglion cells depending on the distance of axotomy in adult hamsters

PURPOSE: To examine the relationship between the distance of axotomy and axonal regeneration of injured retinal ganglion cells (RGCs) systematically and the effect of a predegenerated (pretransected or precrushed) peripheral nerve (PN) graft on axonal regeneration of RGCs axotomized at a definite distance (0.5 mm from the optic disc) in comparison with a normal PN graft. METHODS: The optic nerve (ON) was transected intraorbitally at 0.5, 1, 1.5, 2, or 3 mm or intracranially at 6 to 8 mm from the optic disc, and a PN graft was transplanted onto the ocular ON stump in adult hamsters. Four weeks after grafting, the number of RGCs regenerating their injured axons into the PN graft was investigated in all animals. RESULTS: The number of regenerating RGCs decreased significantly when the distance of axotomy increased from 0.5 to 7 mm. A precrushed PN graft was shown to enhance more injured RGCs to regenerate axons than a normal or pretransected PN graft. CONCLUSIONS: The distance of axotomy on the ON of adult hamsters is critical in determining the number of regenerating RGCs. Thus, experimental strategies to repair the damaged ON by PN transplantation is to attach a precrushed PN graft as close to the optic disc as possible to obtain optimal axonal regeneration of the axotomized RGCs.     

Survival and axonal regeneration of retinal ganglion cells in adult cats

Axotomized retinal ganglion cells (RGCs) in adult cats offer a good experimental model to understand mechanisms of RGC deteriorations in ophthalmic diseases such as glaucoma and optic neuritis. Alpha ganglion cells in the cat retina have higher ability to survive axotomy and regenerate their axons than beta and non-alpha or beta (NAB) ganglion cells. By contrast, beta cells suffer from rapid cell death by apoptosis between 3 and 7 days after axotomy. We introduced several methods to rescue the axotomized cat RGCs from apoptosis and regenerate their axons; transplantation of the peripheral nerve (PN), intraocular injections of neurotrophic factors, or an antiapoptotic drug. Apoptosis of beta cells can be prevented with intravitreal injections of BDNF+CNTF+forskolin or a caspase inhibitor. The injection of BDNF+CNTF+forskolin also increases the numbers of regenerated beta and NAB cells, but only slightly enhances axonal regeneration of alpha cells. Electrical stimulation to the cut end of optic nerve is effective for the survival of axotomized RGCs in cats as well as in rats. To recover function of impaired vision in cats, further studies should be directed to achieve the following goals: (1) substantial number of regenerating RGCs, (2) reconstruction of the retino-geniculo-cortical pathway, and (3) reconstruction of retinotopy in the target visual centers.     

Cataractogenic lens injury prevents traumatic ganglion cell death and promotes axonal regeneration both in vivo and in culture

PURPOSE: To examine and quantify neuroprotective and neurite-promoting activity on retinal ganglion cells (RGCs) after injury of the lens. METHODS: In adult albino rats, penetrating lens injury was performed by intraocular injection. To test for injury-induced neuroprotective effects in vivo, fluorescence-prelabeled RGCs were axotomized by subsequent crush of the optic nerve (ON) with concomitant lens injury to cause cataract. The numbers of surviving RGCs were determined in retinal wholemounts and compared between the different experimental and control groups. To examine axonal regeneration in vivo, the ON was cut and replaced with an autologous piece of sciatic nerve (SN). Retinal ganglion cells with axons that had regenerated within the SN under lens injury or control conditions were retrogradely labeled with a fluorescent dye and counted on retinal wholemounts. Neurite regeneration was also studied in adult retinal explants obtained either after lens injury or without injury. The numbers of axons were determined after 1 and 2 days in culture. Putative neurotrophins (NTs) were studied within immunohistochemistry and Western blot analysis. RESULTS: Cataractogenic lens injury performed at the same time as ON crush resulted in highly significant rescue of 746 +/- 126 RGCs/mm(2) (mean +/- SD; approximately 39% of total RGCs) 14 days after injury compared with controls without injury or with injection of buffer into the vitreous body (30 +/- 18 RGCs/mm(2)). When lens injury was performed with a delay of 3 days after ON crush, 49% of RGCs survived, whereas delay of 5 days still rescued 45% of all RGCs. In the grafting paradigm virtually all surviving RGCs after lens injury appeared to have regenerated an axon within the SN graft (763 +/- 114 RGCs/mm(2) versus 79 +/- 17 RGCs/mm(2) in controls). This rate of regeneration corresponds to approximately 40% of all RGCs. In the regeneration paradigm in vitro preceding lens injury and ON crush 5 days previous resulted in a maximum of regeneration of 273 +/- 39 fibers/explant after 1 day and 574 +/- 38 fibers/explant after 2 days in vitro. In comparison, in control retinal pieces without lens injury 28 +/- 13 fibers/explant grew out at 1 day, and 97 +/- 37 fibers/explant grew out at 2 days in culture. Immunohistochemical and Western blot analysis of potential NTs in the injured lens revealed no expression of ciliary neurotrophic factor (CNTF), brain-derived neurotrophic factor (BDNF), NT-4, nerve growth factor (NGF), and basic fibroblast growth factor (bFGF). CONCLUSIONS: The findings indicate that the lens contains high neuroprotective and neuritogenic activity, which is not caused by NT. Compared with the data available in the literature, this neuroprotection is quantitatively among the highest ever reported within the adult rat visual system.     

Survival of axotomized retinal ganglion cells in peripheral nerve-grafted ferrets.

PURPOSE: Peripheral nerve (PN) grafting to the optic nerve stump stimulates not only axonal regeneration of the axotomized retinal ganglion cells (RGCs) into the grafted PN but also their survival. The purpose of the present study was to determine the number, distribution, and soma diameter of only surviving RGCs without regenerated axons and surviving RGCs with regenerated axons in PN-grafted mammals. METHODS: A segment of PN was grafted to the optic nerve stump of adult ferrets. Two months after the PN grafting, surviving RGCs with regenerated axons were retrogradely labeled with granular blue (GB) and stained with RGC-specific antibody C38. Surviving RGCs without regenerated axons were identified as C38-positive cells without GB labeling. RESULTS: Twenty-one percent of RGCs survived axotomy after PN grafting in the area centralis (AC), whereas 47% survived in the peripheral retina. Twenty-six percent of surviving RGCs in the AC exhibited axonal regeneration, which was higher than that in the peripheral retina. Soma diameter histograms revealed that RGCs with regenerated axons showing both GB and C38 positivity were in the large soma diameter ranges. In contrast, the soma diameter distribution of surviving RGCs that did not have regenerated axons showed a peak in the smaller soma diameter ranges. CONCLUSIONS: The present data suggest that PN grafting promotes survival of axotomized RGCs more effectively in the peripheral retina than in the AC. Among surviving RGCs, the larger cells exhibited axonal regeneration into the grafted PN, whereas the axons of smaller cells did not to regenerate in either the AC or the peripheral retina.     

c-Jun expression in surviving and regenerating retinal ganglion cells: effects of intravitreal neurotrophic supply

PURPOSE: To investigate c-jun expression in surviving and axon-regenerating retinal ganglion cells (RGCs) and the effect of intravitreal neurotrophic supply on c-jun expression. METHODS: All animals underwent optic nerve transection (ONT) 0.5 mm behind the eyeball. Some animals underwent a replacement of the optic nerve with an autologous sciatic nerve graft (SNG) to allow axonal regrowth. To provide a neurotrophic supply, a peripheral nerve (PN) segment or brain-derived neurotrophic factor (BDNF)/ciliary neurotrophic factor (CNTF) was applied intravitreally. The time course of c-jun expression was first examined in both surviving and regenerating RGCs. Then, c-jun expression was examined in surviving and regenerating RGCs 3 weeks after intravitreal BDNF/CNTF treatment. Animals with vehicle eye injection were used as the control. Fluorescent dye was used for retrograde labeling of surviving (applied behind the eyeball) and regenerating (applied at the distal end of the SNG) RGCs. All retinas were immunohistochemically stained for c-jun. RESULTS: c-Jun was not detected in normal RGCs, but weak expression was seen in surviving RGCs after ON injury. The proportion of c-jun-positive (+) RGCs among surviving cell population was 52.6% to 86.5% 2 to 6 weeks after ONT. Among regenerating RGCs, more than 80% expressed c-jun in all treatment groups, a proportion that was significantly higher after CNTF treatment (90.7%). In addition, c-jun expression was much stronger in intensity and the c-jun(+) nuclei were much larger in regenerating than in surviving RGCs. CONCLUSIONS: c-Jun expression in RGCs was upregulated after injury. Most regenerating RGCs were c-jun(+), and the intensity of c-jun expression was higher in regenerating than in surviving RGCs. CNTF also upregulated c-jun expression in RGCs.     

细胞因子对视网膜神经元保护和诱导作用的研究进展

近年来细胞因子在视网膜功能重建中的作用已初见端倪。研究发现,脑源性神经营养因子、睫状神经营养因子、碱性成纤维细胞生长因子及神经营养素4可以防止视网膜光感受器细胞变性的发生,增强光感受器细胞损伤后的修复,促进视网膜神经节细胞的发育,刺激神经节细胞轴突的再生。同时,晶状体上皮源性生长因子及人羊膜上皮细胞分泌的细胞因子也对神经节细胞有保护效应。而神经营养素-3在视网膜的作用性质还有待更多的研究。（中华眼科杂志,2005,41：861-864）     

Promoting optic nerve regeneration

Vision is the most important sense for humans and it is irreversibly impaired by axonal damage of retinal ganglion cells (RGCs) in the optic nerve due to the lack of axonal regeneration. The failure of regeneration is partially attributable to factors located in the inhibitory environment of the forming glial scar and myelin as well as an insufficient intrinsic ability for axonal regrowth. Moreover, RGCs undergo apoptotic cell death after optic nerve injury, eliminating any chance for regeneration. In this review, we discuss the different aspects that cause regenerative failure in the optic nerve. Moreover, we describe discoveries of the last two decades demonstrating that under certain circumstances mature RGCs can be transformed into an active regenerative state allowing these neurons to survive axotomy and to regenerate axons in the injured optic nerve. In this context we focus on the role of the cytokines ciliary neutrophic factor (CNTF) and leukemia inhibitory factor (LIF), their receptors and the downstream signaling pathways. Furthermore, we discuss strategies to overcome inhibitory signaling induced by molecules associated with optic nerve myelin and the glial scar as well as the regenerative outcome after combinatorial treatments. These findings are encouraging and may open the possibility that clinically meaningful regeneration may become achievable one day in the future.     

Axonal regeneration of retinal ganglion cells after optic nerve pre-lesions and attachment of normal or pre-degenerated peripheral nerve grafts

Axonal regeneration of retinal ganglion cells (RGCs) into a normal or pre-degenerated peripheral nerve graft after an optic nerve pre-lesion was investigated. A pre-lesion performed 1-2 weeks before a second lesion has been shown to enhance axonal regeneration in peripheral nerves (PN) but not in optic nerves (ON) in mammals. The lack of such a beneficial pre-lesion effect may be due to the long delay (1-6 weeks) between the two lesions since RGCs and their axons degenerate rapidly 1-2 weeks following axotomy in adult rodents. The present study examined the effects of the proximal and distal ON pre-lesions with a shortened delay (0-8 days) on axonal regeneration of RGCs through a normal or pre-degenerated PN graft. The ON of adult hamsters was transected intraorbitally at 2 mm (proximal lesion) or intracranially at 7 mm (distal lesion) from the optic disc. The pre-lesioned ON was re-transected at 0.5 mm from the disc after 0, 1, 2, 4, or 8 days and a normal or a pre-degenerated PN graft was attached onto the ocular stump. The number of RGCs regenerating their injured axons into the PN graft was estimated by retrograde labeling with FluoroGold 4 weeks after grafting. The number of regenerating RGCs decreased significantly when the delay-time increased in animals with both the ON pre-lesions (proximal or distal) compared to control animals without an ON pre-lesion. The proximal ON pre-lesion significantly reduced the number of regenerating RGCs after a delay of 8 days in comparison with the distal lesion. However, this adverse effect can be overcome, to some degree, by a pre-degenerated PN graft applied 2, 4, or 8 days after the distal ON pre-lesion enhanced more RGCs to regenerate than the normal PN graft. Thus, in order to obtain the highest number of regenerating RGCs, a pre-degenerated PN should be grafted immediately after an ON lesion.     

Optic Nerve Engraftment of Neural Stem Cells

PurposeTo evaluate the integrative potential of neural stem cells (NSCs) with the visual system and characterize effects on the survival and axonal regeneration of axotomized retinal ganglion cells (RGCs).MethodsFor in vitro studies, primary, postnatal rat RGCs were directly cocultured with human NSCs or cultured in NSC-conditioned media before their survival and neurite outgrowth were assessed. For in vivo studies, human NSCs were transplanted into the transected rat optic nerve, and immunohistology of the retina and optic nerve was performed to evaluate RGC survival, RGC axon regeneration, and NSC integration with the injured visual system.ResultsIncreased neurite outgrowth was observed in RGCs directly cocultured with NSCs. NSC-conditioned media demonstrated a dose-dependent effect on RGC survival and neurite outgrowth in culture. NSCs grafted into the lesioned optic nerve modestly improved RGC survival following an optic nerve transection (593 ± 164 RGCs/mm² vs. 199 ± 58 RGCs/mm²; P < 0.01). Additionally, RGC axonal regeneration following an optic nerve transection was modestly enhanced by NSCs transplanted at the lesion site (61.6 ± 8.5 axons vs. 40.3 ± 9.1 axons, P < 0.05). Transplanted NSCs also differentiated into neurons, received synaptic inputs from regenerating RGC axons, and extended axons along the transected optic nerve to incorporate with the visual system.ConclusionsHuman NSCs promote the modest survival and axonal regeneration of axotomized RGCs that is partially mediated by diffusible NSC-derived factors. Additionally, NSCs integrate with the injured optic nerve and have the potential to form neuronal relays to restore retinofugal connections.     

Axotomized mouse retinal ganglion cells containing melanopsin show enhanced survival, but not enhanced axon regrowth into a peripheral nerve graft

Melanopsin is found in only approximately 2% of mouse retinal ganglion cells (RGCs), making these RGCs uniquely and directly photosensitive. Given that the majority of RGCs die after axotomy and that grafting of a peripheral nerve to the eye provides a permissive environment for axon regrowth, the present study examined the survival and axonal regrowth of melanopsin-containing RGCs in mice. One month after optic nerve transection and grafting, RGCs with regrown axons were labeled from the grafts and retinae were processed to visualize melanopsin and TUJ1. Melanopsin-positive and negative RGCs were counted and compared to axotomized RGCs from ungrafted eyes and uninjured RGCs. Melanopsin-positive RGCs showed a 3-fold increase in survival rate compared to non-melanopsin RGCs. Despite this enhanced survival, melanopsin-containing RGCs did not show increased axon regrowth into nerve grafts.     

Chemotactic effect of ciliary neurotrophic factor on macrophages in retinal ganglion cell survival and axonal regeneration

PURPOSE: To examine whether ciliary neurotrophic factor (CNTF) has a chemotactic effect on macrophages and whether macrophages are involved in CNTF-induced retinal ganglion cell (RGC) survival and axonal regeneration after optic nerve (ON) injury. METHODS: Adult Fischer 344 rats received an autologous peripheral nerve graft onto transected ON for injured axons to grow. CNTF was applied intravitreally. When needed, clodronate liposomes were applied intravitreally or intravenously to deplete macrophages in the eye. A chemotaxis microchamber system was used to examine whether CNTF has a chemotactic effect on macrophages in vitro, whereas immunohistochemistry was used to identify the location of macrophages/microglia in the retina. The effects of CNTF on RGC neurite outgrowth and macrophage/microglia proliferation were tested in retinal explants. RESULTS: Intravitreal CNTF significantly enhanced RGC survival and axonal regeneration as well as the number of macrophages in the eye. Removal of macrophages significantly reduced CNTF-induced RGC survival and axon regeneration. A chemotaxis assay showed a clear chemotactic effect of CNTF on blood-derived but not peritoneal macrophages. Immunohistochemistry revealed that local microglia was located in a region from the nerve fiber layer (NFL) to the inner nuclear layer, whereas blood-derived macrophages were in the NFL. In vitro experiments revealed that CNTF did not enhance neurite outgrowth or macrophage/microglia proliferation in retinal explants. CONCLUSIONS: CNTF is a chemoattractant but not a proliferation enhancer for blood-derived macrophages, and blood-borne macrophages recruited into the eye by CNTF participate in RGC protection. This finding thus adds an important category to the existing understanding of the biological actions of CNTF.     

细胞因子对视神经损伤修复作用的研究进展

创伤、代谢、高眼压等多种因素均可能造成视网膜神经节细胞和或视神经损伤，而视网膜神经节细胞损伤凋亡后无法自主再生，因此往往会造成视力下降甚至丧失等严重后果。对于视神经损伤，目前临床上尚无非常有效的治疗方法。近年有研究发现细胞因子可以明显促进视网膜神经节细胞的存活和轴突再生。本文就其中睫状神经营养因子、胶质源性神经营养因子、色素上皮衍生因子、粒细胞集落刺激因子、血浆凝血因子、促红细胞生成素等几种细胞因子促进视神经损伤修复作用的研究进展进行综述。     

Retinal ganglion cell axotomy induces an increase in intracellular superoxide anion

PURPOSE: Retinal ganglion cells (RGCs) undergo apoptosis after axonal injury. The time course of cell death is variable and depends in part on the degree of injury sustained. Decreasing reactive oxygen species (ROS) levels or shifting the redox state to reduction promotes the survival of RGCs in tissue culture after axotomy. It was hypothesized that a specific ROS, superoxide anion, acts as an intracellular signaling molecule for RGC death after axotomy. METHODS: Intracellular superoxide levels were measured after dissociation in retrograde-labeled rat RGCs with use of the superoxide-sensitive fluorophores hydroethidium and MitoSOX Red. Having found a significant increase, the effect of axotomy was determined on superoxide levels independent of dissociation with an optic nerve crush model. RESULTS: Optic nerve crush caused RGCs to undergo a superoxide burst. The burst was asynchronous and was manifested in only a fraction of cells at any given time. Neurotrophin deprivation was not responsible for the superoxide burst because it was not prevented by incubation with the neurotrophic factors brain-derived neurotrophic factor, ciliary neurotrophic factor, forskolin, or insulin. Several inhibitors of intracellular superoxide generation were studied, but only antimycin A, which inhibits complex III of the mitochondrial electron transport chain, blocked the increase in superoxide. CONCLUSIONS: These findings suggest that superoxide generated in the mitochondrial electron transport chain could be a parallel system to neurotrophic deprivation for signaling cell death after axonal injury.     

移植含嗅鞘细胞和体外溃变的周围神经对成年大鼠视网膜神经节细胞轴突再生作用的比较

目的比较含嗅鞘细胞（OEC）或（和）体外溃变的周围神经移植对成年大鼠视网膜神经节细胞（RGC）轴突再生的影响。方法将24只成年雄性Sprague-Dawley大鼠随机分为4组，每组各6只大鼠：A组（周围神经对照组）：将取出的一段自体坐骨神经与眶内切断的左侧视神经近侧断端吻合；B组（OEC注入周围神经组）：自取出的坐骨神经两端注入10 μl OEC悬液后移植于视神经断端。C组（周围神经体外溃变组）：将取出的坐骨神经在体外单独培养5 d后植于视神经断端；D组（OEC-周围神经共培养组）：将取出的坐骨神经与OEC共培养5d后植于视神经断端。移植术后4周处死动物，计数各组以5%荧光金逆行标记的再生RGC数量。结果B、C、D三组RGC均数1481±268、1235±266和1464±285显著高于A组799±109（P值分别为0.0002、0.0010和0.0003）；B、C、D三组间差异无统计学意义（P值分别为0.3644、0.9167和0.4344）。结论OEC具有促进RGC轴突在新鲜周围神经移植物中再生的作用，但这种作用与体外溃变的周围神经相比无明显差异，二者亦无协同作用。（中华眼底病杂志，2007，23：130-132）     

视网膜下移植睫状神经营养因子编码基因修饰的细胞保护SD大鼠视神经横断伤后视网膜节细胞变性

目的探讨移植表达睫状神经营养因子(CNTF)的细胞对SD大鼠视神经横断伤后视网膜节细胞的保护作用。方法通过脂质体将CNTF表达质粒转移至人胚肺成纤维细胞,建立稳定、高水平表达CNTF的细胞株。采用双侧背外侧膝状体及上丘核团注射3%荧光金逆行标记视网膜节细胞。将标记后的大鼠分为两组,于标记后7d手术切断眶内段视神经其中一组左眼不做手术作为正常对照组,右眼切断视神经作为手术对照组;另一组双眼均手术切断视神经,左眼注射PBS作为治疗对照组,右眼视网膜下移植表达CNTF的细胞作为实验组。术后5、14、17、21及28d取出眼球,铺片后荧光显微镜观察并计数视网膜内存活的节细胞。结果手术切断眶内段视神经后2周,视网膜内节细胞数减少6744%,视网膜下移植表达CNTF的细胞后第5、17、21d视网膜内存活的节细胞数明显多于治疗对照组(P<005)。结论视网膜下移植高水平表达CNTF的细胞对视网膜节细胞有保护作用。     

Activation of MAPK and CREB by GM1 induces survival of RGCs in the retina with axotomized nerve

PURPOSE: Neuronal cells undergo apoptosis when the supply of neurotrophic factor is limited by injury, trauma, or neurodegenerative disease. Ganglioside has both neuritogenic and neurotropic functions. Exogenously administered monosialoganglioside (GM1) has been shown to have a stimulatory effect on neurite outgrowth and to prevent degeneration of neuronal cells in the central nervous system. Even though GM1 has been shown to mimic, or have synergy with, neurotrophic factors, the neuroprotective mechanism of GM1 has not been well understood. In this study, optic nerve transection, or axotomy, was used as an in vivo model system for injury, to examine the protective mechanism of GM1 in injured retinal ganglion cells. METHODS: GM1 was injected into the vitreous body before axotomy, and the protective effect of GM1 observed with regard to activation of mitogen-activated protein kinase (MAPK) and phosphorylation of cAMP-responsive element-binding (CREB) protein. Activation of MAPK and CREB were examined by Western blot analysis and immunohistochemistry, and the surviving retinal ganglion cells were counted after retrograde fluorescence labeling. RESULTS: GM1 inhibited the degeneration of axotomized retinal ganglion cells. In addition, GM1 enhanced the activation of MAPK and CREB with the treatment of GM1 in the retina with axotomized nerve. Treatment of MAPK inhibitor PD98059 with GM1 reduced the protective action of GM1 and prevented GM1-induced phosphorylation of CREB. CONCLUSIONS: GM1 protected the axotomized retinal ganglion cells (RGCs) from cell death after axotomy through the activation of MAPK and CREB.     

Brain-derived neurotrophic factor and repair of retinal ganglion cells after injury

Blocking of retrograde transport after the optic nerve injury results in deprivation of neurotrophic support to retinal ganglion cells (RGCs), and leads to apoptotic cell death in glaucoma. As an important member of neurotrophins, the brain-derived neurotrophic factor (BDNF) plays a substantial role in the repair of retinal ganglion cells injury, but its signaling pathway in the pathogenesis of glaucoma remains unclear. This review focuses on the structure, distribution and receptors of BDNF and its effects on RGC survival, axon regeneration and relevant signaling pathway, to provide theoretical foundation for neuroprotective treatment of glaucoma.     

In vivo expression of neurotrophins and neurotrophin receptors is conserved in adult porcine retina in vitro

PURPOSE. To characterize and compare the expression of neurotrophins (NTs) and their receptors within adult porcine retinal ganglion cells (RGCs) in vivo and in vitro. METHODS. The distribution of nerve growth factor (NGF), brain-derived neurotrophic factor (BDNF), neurotrophin-3 (NT-3) and -4 (NT-4), and their high-affinity receptors TrkA, TrkB, TrkC and low-affinity receptor p75, was analyzed in adult porcine retinal sections by immunohistochemistry. In addition, adult porcine retinas were dissociated and cultured in four different conditions: control, semipure RGCs, supplemented with BDNF, or seeded on Müller glia feeder layers. Double immunostaining was performed with antibodies to NTs or their receptors combined with neurofilament antibody to identify RGCs in culture. RESULTS. In vivo, immunolabeling of NGF was very faint, BDNF was especially prominent in RGCs and inner nuclear layer cells, NT-3 stained widespread nuclei, and NT-4 was undetectable. TrkA immunoreactivity was visible in the nerve fiber layer, TrkB staining was within RGC bodies, TrkC was undetectable, and p75 was widely expressed across the retina, within the Müller glia. Expression of neurotrophins and their receptors was maintained in all four models of adult RGCs in vitro, showing that expression was not influenced by substrate or culture conditions. We observed prominent staining of TrkA within growth cones, and a clear expression of p75 within a subpopulation of RGCs in vitro. CONCLUSIONS. These findings demonstrate that the expression of NTs and their receptors within adult porcine RGCs is maintained in vitro, under conditions of limited interaction with neighboring neurons and deprived of afferent inputs and target tissue. TrkA may be involved in regeneration of nerve terminals.     

CNTF and BDNF have similar effects on retinal ganglion cell survival but differential effects on nitric oxide synthase expression soon after optic nerve injury

PURPOSE: To investigate the effect of ciliary neurotrophic factor (CNTF) and brain-derived neurotrophic factor (BDNF) on retinal ganglion cell (RGC) survival and nitric oxide synthase (NOS) expression in the retina during the early phase of optic nerve (ON) injury, and to examine whether intraperitoneal application of the NOS scavenger nitro-l-arginine (l-NA) could protect the injured RGCs. METHODS: RGCs were retrogradely labeled with granular blue 3 days before the ON was intraorbitally transected. RGC survival was examined 1 week after ON transection and intraocular injection of CNTF and/or BDNF, or 1 to 2 weeks after daily intraperitoneal injection of the NOS inhibitor l-NA. NOS expression was examined by NADPH-diaphorase histochemistry and neuronal NOS (nNOS) immunohistochemistry, and nNOS-positive cells were identified by various staining approaches. RESULTS: Both CNTF and BDNF significantly increased RGC survival 1 week after ON injury. In the ganglion cell layer (GCL), CNTF did not increase the number of NADPH-diaphorase positive ((+)) cells but appeared to reduce the intensity of NADPH-diaphorase staining, whereas BDNF increased the number of NADPH-diaphorase(+) cells and also appeared to enhance the intensity of NADPH-diaphorase staining. In the GCL, amacrine cells but not RGCs were nNOS(+). Some macrophages were also nNOS(+). In contrast, no amacrine cells were nNOS(+) in the inner nuclear layer. Daily intraperitoneal injection of l-NA at appropriate concentrations promoted RGC survival for 1 or 2 weeks after ON injury. CONCLUSIONS: Both CNTF and BDNF protected RGCs after ON injury. CNTF and BDNF acted differently on NOS expression in the GCL. Intraperitoneal injections of l-NA at appropriate dosages enhance RGC survival.