The Neurotrophin Receptors TrkA and TrkB are Inhibitory for Neurite Outgrowth

To investigate the possibility that the neurotrophin tyrosine kinase receptors are also recognition molecules by virtue of their immunoglobulin-like domains, the ability of TrkA and TrkB to influence neurite outgrowth was tested in vitro. Cell monolayers of fibroblasts transfected to express either the TrkA or TrkB receptor reduced neurite outgrowth of phaeochromocytoma PC12 cells by 50–60% when compared to mock transfected fibroblasts or fibroblasts transfected with the epidermal growth factor receptor. Neurite outgrowth from cerebellar neurons was inhibited by 30–40% on these substrates. When a recombinantly expressed fragment of TrkA comprising the two immunoglobulin-like domains was coated as a substrate in combination with poly-L-lysine and laminin, neurite outgrowth was inhibited in a dose-dependent manner. This inhibition of neurite outgrowth was not mediated via an interaction with laminin as there is no specific binding of the TrkA fragment to laminin. The adhesion of cell bodies to this substrate was not affected by the immunoglobulin-like domains. These observations suggest that the mammalian neurotrophin receptors not only influence neurite outgrowth by neurotrophin triggered activation of the receptor, but also by cell surface recognition processes conveyed by the immunoglobulin-like domains.     

Manganese induces spreading and process outgrowth in rat pheochromocytoma (PC12) cells

Mn²⁺ has been shown to promote cell–substrate adhesion and cell spreading in many cell culture systems. In this study, we present data demonstrating that Mn²⁺ not only promotes spreading, but also induces process outgrowth in rat pheochromocytoma (PC12) cells. In the presence of 1.0 mM MnCl₂, cell spreading was apparent by 6 hr, and nearly 50% of the exposed cells extended neurite-like processes. These morphological effects of Mn²⁺ were both time- and dose-dependent. In the presence of cycloheximide, a protein synthesis inhibitor, both Mn²⁺-induced spreading and neurite outgrowth were prevented, indicating that de novo protein synthesis is required for the effects of Mn²⁺ to take place. Of the other divalent cations tested, Mg²⁺, Cd²⁺, Cu²⁺, Ni²⁺, and Zn²⁺ were ineffective, and only Co²⁺ partially mimicked the effects of Mn²⁺. Although Mn²⁺-induced cell adhesion and spreading have been extensively studied, this is the first report that this divalent cation can cause neurite outgrowth. The neurite outgrowth-promoting effects of Mn²⁺ were distinct from those of nerve growth factor in that the response to Mn²⁺ was considerably more rapid, but apparently lacked the ability to sustain continuous outgrowth and networking of neurites. Mn²⁺ also induced the levels of GAP-43 and peripherin, two proteins associated with neuronal differentiation of PC-12 cells. In cells grown in serum-free defined medium, Mn²⁺ was capable of promoting neurite outgrowth when the cells were plated on surfaces pretreated with normal growth medium, vitronectin, or fibronectin, while it failed to cause these morphological changes in cells plated on untreated or poly-D-lysine-coated substrata. Similarly, Mn²⁺ also promoted neurite outgrowth from rat sympathetic neurons attached to laminin-treated substrate, but had no effect on neurons maintained on substrate with polylysine only. The pentapeptide Gly-Arg-Gly-Asp-Ser nearly completely prevented the morphological effects of Mn²⁺ on PC12 cells. These findings are consistent with a hypothesis that Mn²⁺-mediated alteration of an RGD-dependent extracellular matrix-integrin interaction is responsible for the neuritogenic effects. © 1993 Wiley-Liss, Inc.     

中风前抗轴突生长抑制因子DNA免疫促进脑缺血功能康复

目的证实中风前抗轴突生长抑制因子DNA免疫对脑缺血神经功能康复的促进作用。方法经腓肠肌注射抗轴突生长抑制因子DNA疫苗免疫动物，每周一次、共6周；血清中检测出相关抗体后，采用永久性阻断大脑中动脉的方法制备左侧局部脑缺血模型；分别采用改良的神经病严重程度记分、被动逃避试验和悬臂迷宫试验评价运动功能、认知行为和焦虑样情感的。结果中风前接受抗轴突生长抑制因子DNA免疫，局部脑缺血后出现明显的运动恢复，但是认知行为和焦虑样情感障碍则没有明显改善。结论中风前抗轴突生长抑制因子DNA免疫可促进脑缺血后的运动功能恢复。     

Olivocerebellar Axon Regeneration and Target Reinnervation Following Dissociated Schwann Cell Grafts in Surgically Injured Cerebella of Adult Rats

The ability of Schwann cells to induce the regeneration of severed olivocerebellar and Purkinje cell axons across an injury up to their deafferented targets was tested by transplanting freshly dissociated cells from newborn rat sciatic nerves into surgically lesioned adult cerebella. The grafted glial cells consistently filled the lesion gap and migrated into the host parenchyma. Transected olivocerebellar axons vigorously regenerated into the graft, where their growth pattern and direction followed the arrangement of Schwann cell bundles. Although some of these axons terminated within the transplant, many of them rejoined the cerebellar parenchyma beyond the lesion. Here, their fate depended on the territory encountered. No growth occurred in the white matter. Numerous fibres penetrated into the granular layer and formed terminal branches that remained confined within this layer. A few of them, however, regenerated up to the molecular layer and formed climbing fibres on Purkinje cell dendrites. By contrast, the growth of transected Purkinje cell axons into the grafts was very poor. These results underscore the different intrinsic responsiveness of Purkinje cell and olivocerebellar axons to the growth-promoting action of Schwann cells, and show that the development and outcome of the regenerative phenomena is strongly conditioned by the spatial organization and specific features of the environmental cues encountered by the outgrowing axons along the course they follow. However, Schwann cells effectively bridge the lesion gap, induce the regeneration of olivocerebellar axons, and direct their growth up to the deafferented host cortex, where some of them succeed in reinnervating their natural targets.     

Design,synthesis, tandem mass spectrometric sequencing and biological activity of NGF mimetics

Nine low molecular weight nerve growth factor (NGF)-like peptides have been designed to mimic the putative receptor-binding epitope of NGF defined by two β-hairpin loops. Eight different spacers were used as variable links between the β-loop amino acid residues, which from mutagenesis experiments were found to play an important role in the biological activity of NGF. These spacers were amino acids, natural or non-natural, differing in length (5–13 Å) and polarity. The peptides were synthesized via the Fmoc solid-phase peptide synthesis and purified by reversed-phase HPLC. Their primary sequences were analyzed by a combination of automated Edman degradation and mass spectrometry. The peptides were tested using two different biological assays, the fibre outgrowth from chick embryonic sympathetic ganglia and the PC 12 cell differentiation assay. Weak antagonistic effects could be observed for some peptides. © Munksgaard 1996.     

Neuronal migration in cerebellar microcultures is inhibited by antibodies against a neurite outgrowth domain of laminin.

The functional role of laminin in neuronal migration was investigated by using polyclonal antibodies or their divalent (Fab')2 fragments to a neurite outgrowth promoting domain of the B2 chain of laminin in a cerebellar microculture system widely recognized as a model for neuronal migration. We show here that these antibodies or their (Fab')2 fragments totally inhibit migration of the mouse cerebellar granule cells along the glial and other neuronal cell processes. Antibodies to native laminin or other control antibodies have no inhibitory effect. Immunocytochemical analysis of the cerebellar microcultures indicates that the functional role of these antibodies may relate to the fact that the punctate deposits of laminin and its neurite outgrowth promoting domain accumulate in between the migrating neurons and the glial cells. These data provide the first direct evidence for the functional role of laminin and its neurite outgrowth domain in neuronal migration in the mammals. They further suggest that a neuronal cell surface contact with the extracellular deposits of a neurite outgrowth domain of the B2 chain of laminin may mediate neuronal-glial interactions.     

Effects of insulin, insulin-like growth factor-II and nerve growth factor on neurite outgrowth in cultured human neuroblastoma cells

The identification of biologically important and chemically well-defined substances that can promote axon and dendrite formation would improve present understanding of the development of the nervous system. Physiological concentrations of insulin and insulin-like growth factor-II (IGF-II) reversibly enhanced neurite outgrowth (NTO) in human neuroblastoma SH-SY5Y cells cultured in media with and without serum. Nerve growth factor (NGF), in contrast, did not enhance NTO in serum-free media. Furthermore, anti-NGF antiserum inhibited NGF but not insulin-enhanced NTO. Insulin increased [3H]leucine and [3H]uridine uptake. These increases, together with increased NTO, were inhibited by cycloheximide and actinomycin D, respectively. The inhibition of NTO by cycloheximide was reversible. Human neuroblastoma cell lines that were responsive by NTO to NGF were also responsive to insulin, with the exception of line CHP-270. Moreover, cell lines unresponsive by NTO to NGF, and to tumor promoters, were uniformly unresponsive to insulin. These findings suggest that there are common defects in distal sites, because specific NGF and tumor promotor receptors are present in these lines. Insulin increased [3H]thymidine uptake in SH-SY5Y and CHP-100 cells. However, the enhancement of NTO by insulin and IGF-II in SH-SY5Y cells was independent of the cellular proliferation rate. Our results, together with the observations of others, suggest that insulin and IGF-II may modulate NTO in the nervous system.     

Neurons cultured from developing rat brain attach and spread preferentially to laminin

Neurons, mechanically dissociated from newborn rat brain and identified by immunostaining for neurofilaments, attached preferentially to laminin-coated coverslips without need of an underlying glial monolayer. The most extensive neurite outgrowth was seen when 20-30 micrograms/ml of laminin was used to coat the coverslips. Higher concentrations of laminin (greater than 30 micrograms/ml) supported single neurons to spread on the coverslips. Fibronectin coating of the coverslips allowed glial cells to attach more rapidly than on uncoated surfaces, but it did not support neuronal spreading or neurite outgrowth. Spreading of neurons and neurite outgrowth were completely inhibited by preincubation of laminin-coated coverslips with laminin antibodies but were unaffected by fibronectin antibodies. These results indicate that laminin is an attachment and spreading factor for central neurons in culture and suggest the presence of a laminin receptor on the neuronal cell surfaces.     

Polyornithine-attached neurite-promoting factors (PNPFs). Culture sources and responsive neurons

We have recently reported the existence within chick embryo heart cell conditioned medium (HCM) of two distinct and independently assayable factors. One agent, ciliary neuronotrophic factor (CNTF), supports the in vitro survival of 8-day chick embryo ciliary ganglionic (CG) neurons. The other factor, polyornithine-attachable neurite promoting factor (PNPF) is required for extensive neuritic growth from these same CNTF-supported CG neurons.In the present study we have examined the occurrence of PNPF activity within nearly 100 different conditioned media using our previously described chick CG bioassay system. From this screening we conclude that: (1) PNPF production is a rather widespread property of cultured neural as well as non-neural cells; and (2) the chick bioassay is sensitive to PNPF activity from all the species examined, including mouse, rat, human and chick cells.We next examined the effects of 3 representative PNPF-containing conditioned media (from chick heart, mouse Schwann and rat Schwannoma) on neurite production from 3 other peripheral ganglionic neuronal cultures (8-day chick dorsal root, 11-day chick sympathetic, and neonatal mouse dorsal root ganglia) as well as 4 central neuronal cultures (8-day chick embryo telencephalon, optic lobe and spinal cord and neonatal mouse cerebellum). The results of these studies indicate: (1) that the peripheral neurons exhibit a dramatic increase in neurite production in response to PNPF which can be easily recognized both qualitatively and quantitatively; whereas (2) the CNS neurons showed essentially no PNPF-induced increase in neurite production. The sole exception to the latter was the appearance within the chick spinal cord cultures of a neuronal population which extended very long neurites in response to PNPF.     

Involvement of γ and β Actin Isoforms in Mouse Neuroblastoma Differentiation

Two actin isoforms, γ and β, are contained within neuroblastoma cells. However, the relative amount and distribution of both isoforms within the cells are differentially regulated during neurite extension. The proportion of γ actin isoform became about four times greater than that of β actin during neuroblastoma cell differentiation. Additionally, whereas β actin appears to be concentrated in the cell cortex, γ actin is also present throughout the cell body. Upon differentiation, neuroblastoma cells reorganize their actin cytoskeleton and γ actin is induced to polymerize whereas β actin polymers are partially disassembled. Moreover, both actin isoforms are differentially distributed within differentiated cells. Thus, γ actin polymers are located both in the soma and proximal regions of extended neurites, whereas β actin is enriched in the terminal tip of the neurites. Our results strongly suggest that both actin isoforms are involved in a different way in neuroblastoma cell differentiation.