Prevention of thrombin-induced motoneuron degeneration with different neurotrophic factors in highly enriched cultures

Previous reports have shown that neuronal and glial cells express functionally active thrombin receptors. The thrombin receptor (PAR-1), a member of a growing family of protease activated receptors (PARs), requires cleavage of the extracellular amino-terminus domain by thrombin to induce signal transduction. Studies from our laboratory have shown that PAR-1 activation following the addition of thrombin or a synthetic thrombin receptor activating peptide (TRAP) induces motoneuron cell death both in vitro and in vivo. In addition to increasing motoneuron cell death, PAR- 1 activation leads to decreases in the mean neurite length and side branching in highly enriched motoneuron cultures. It has been suggested that motoneuron survival depends on access to sufficient target-derived neurotrophic factors through axonal branching and synaptic contacts. However, whether the thrombininduced effects on motoneurons can be prevented by neurotrophic factors is still unknown. Using highly enriched avian motoneuron cultures, we show here that alone, soluble chick skeletal muscle extracts (CMX), brain-derived neurotrophic factor (BDNF), ciliary neurotrophic factor (CNTF), and glial cell line-derived neurotrophic factor (GDNF) significantly increased motoneuron survival compared to controls, whereas nerve growth factor (NGF) did not have a significant effect on motoneuron survival. Furthermore, cotreatment with muscle-derived agents (i.e., CMX, BDNF, GDNF) significantly prevented the death of motoneurons induced by alpha-thrombin. Yet, non-muscle-derived agents (CNTF and NGF) had little or no significant effect in reversing thrombin-induced motoneuron death. CMX and CNTF significantly increased the mean length of neurites, whereas NGF, BDNF, and GDNF failed to enhance neurite outgrowth compared to controls. Furthermore, CMX and CNTF significantly prevented thrombin-induced inhibition of neurite outgrowth, whereas BDNF and GDNF only partially reversed thrombin-induced inhibition of neurite outgrowth. These findings show differential effects of neurotrophic factors on thrombin-induced motoneuron degeneration and suggest specific overlaps between the trophic and stress pathways activated by some neurotrophic agents and thrombin, respectively.     

Prevention of thrombin‐induced motoneuron degeneration with different neurotrophic factors in highly enriched cultures

Previous reports have shown that neuronal and glial cells express functionally active thrombin receptors. The thrombin receptor (PAR‐1), a member of a growing family of protease activated receptors (PARs), requires cleavage of the extracellular amino‐terminus domain by thrombin to induce signal transduction. Studies from our laboratory have shown that PAR‐1 activation following the addition of thrombin or a synthetic thrombin receptor activating peptide (TRAP) induces motoneuron cell death both in vitro and in vivo. In addition to increasing motoneuron cell death, PAR‐1 activation leads to decreases in the mean neurite length and side branching in highly enriched motoneuron cultures. It has been suggested that motoneuron survival depends on access to sufficient target‐derived neurotrophic factors through axonal branching and synaptic contacts. However, whether the thrombin‐induced effects on motoneurons can be prevented by neurotrophic factors is still unknown. Using highly enriched avian motoneuron cultures, we show here that alone, soluble chick skeletal muscle extracts (CMX), brain‐derived neurotrophic factor (BDNF), ciliary neurotrophic factor (CNTF), and glial cell line–derived neurotrophic factor (GDNF) significantly increased motoneuron survival compared to controls, whereas nerve growth factor (NGF) did not have a significant effect on motoneuron survival. Furthermore, cotreatment with muscle‐derived agents (i.e., CMX, BDNF, GDNF) significantly prevented the death of motoneurons induced by α‐thrombin. Yet, non–muscle‐derived agents (CNTF and NGF) had little or no significant effect in reversing thrombin‐induced motoneuron death. CMX and CNTF significantly increased the mean length of neurites, whereas NGF, BDNF, and GDNF failed to enhance neurite outgrowth compared to controls. Furthermore, CMX and CNTF significantly prevented thrombin‐induced inhibition of neurite outgrowth, whereas BDNF and GDNF only partially reversed thrombin‐induced inhibition of neurite outgrowth. These findings show differential effects of neurotrophic factors on thrombin‐induced motoneuron degeneration and suggest specific overlaps between the trophic and stress pathways activated by some neurotrophic agents and thrombin, respectively. © 1999 John Wiley & Sons, Inc. J Neurobiol 38: 571–580, 1999     

The response of motoneurons to neurotrophins

The ongoing search for neurotrophic factors for motoneurons has led to the identification of a number of molecules which regulate motoneuron survival and function. Among these factors, the neurotrophins brain derived neurotrophic factor (BDNF), neurotrophin-3 (NT-3) and NT-4/5 but not nerve growth factor (NGF), can prevent embryonic and postnatal motoneuron cell death in a variety of experimental paradigms. Analysis of expression of p75, trkB and trkC—components of the neurotrophin receptors—supports a potential physiological role for these factors as muscle- and glial-derived trophic factors for motoneurons. However, the survival of motoneurons during embryonic development is not reduced in the absence of BDNF, NT-3 or NT-4, as revealed by gene knockout experiments. This points to the involvement of additional trophic factors in the regulation of embryonic and postnatal motoneuron survival. The purpose of this review is to bring together the often prophetic observations from earlier studies—prior to the identification and characterization of these neurotrophins—with more recent results. Special issue dedicated to Dr. Hans Thoenen.     

Neurotrophic factor regulation of developing avian oculomotor neurons: differential effects of BDNF and GDNF.

Neurotrophic factors support the development of motoneurons by several possible mechanisms. Neurotrophins may act as target-derived factors or as afferent factors derived from the central nervous system (CNS) or sensory ganglia. We tested whether brain-derived neurotrophic factor (BDNF), neurotrophin 3 (NT-3), neurotrophin 4 (NT-4), and glial cell line-derived neurotrophic factor (GDNF) may be target-derived factors for neurons in the oculomotor (MIII) or trochlear (MIV) nucleus in chick embryos. Radio-iodinated BDNF, NT-3, NT-4, and GDNF accumulated in oculomotor neurons via retrograde axonal transport when the trophic factors were applied to the target. Systemic GDNF rescued oculomotor neurons from developmental cell death, while BDNF and NT-3 had no effect. BDNF enhanced neurite outgrowth from explants of MIII and MIV nuclei (identified by retrograde labeling in ovo with the fluorescent tracer DiI), while GDNF, NT-3, and NT-4 had no effect. The oculomotor neurons were immunoreactive for BDNF and the BDNF receptors p75(NTR) and trkB. To determine whether BDNF may be derived from its target or may act as an autocrine or paracrine factor, in situ hybridization and deprivation studies were performed. BDNF mRNA expression was detected in eye muscles, but not in CNS sources of afferent innervation to MIII, or the oculomotor complex itself. Injection of trkB fusion proteins in the eye muscle reduced BDNF immunoreactivity in the innervating motoneurons. These data indicate that BDNF trophic support for the oculomotor neurons was derived from their target.     

GDNF及BDNF对受损运动神经元的长期修复

为了研究胶质细胞源神经营养因子（ＧＤＮＦ） 及脑源神经营养因子（ＢＤＮＦ） 对切断轴突的新生运动神经元的长期维持存活及促进神经再生的作用, 我们选用出生时单侧切断坐骨神经的雏鸡模型, 用裸ＤＮＡ 转染方法, 在损伤神经附近的肌肉中转染ＧＤＮＦ ｃＤＮＡ 和ＢＤＮＦ ｃＤＮＡ 的真核表达载体,观察在体表达的神经营养因子对损伤的修复作用。结果显示,在体表达的ＧＤＮＦ 在８ 周内能使切断坐骨神经的腰脊髓运动神经元近９０ ％ 维持存活。切断的坐骨神经从断端向远体端再生,最长再生达９ ．５ｍ ｍ 。表达两个因子比单独表达ＧＤＮＦ 对运动神经元的存活无显著性差异。而两个因子协同作用对坐骨神经的再生更为有效,坐骨神经再生最长的可达１５ ．４ｍ ｍ 。     

Neurotrophic factor regulation of developing avian oculomotor neurons: Differential effects of BDNF and GDNF

Neurotrophic factors support the development of motoneurons by several possible mechanisms. Neurotrophins may act as target‐derived factors or as afferent factors derived from the central nervous system (CNS) or sensory ganglia. We tested whether brain‐derived neurotrophic factor (BDNF), neurotrophin 3 (NT‐3), neurotrophin 4 (NT‐4), and glial cell line–derived neurotrophic factor (GDNF) may be target‐derived factors for neurons in the oculomotor (MIII) or trochlear (MIV) nucleus in chick embryos. Radio‐iodinated BDNF, NT‐3, NT‐4, and GDNF accumulated in oculomotor neurons via retrograde axonal transport when the trophic factors were applied to the target. Systemic GDNF rescued oculomotor neurons from developmental cell death, while BDNF and NT‐3 had no effect. BDNF enhanced neurite outgrowth from explants of MIII and MIV nuclei (identified by retrograde labeling in ovo with the fluorescent tracer DiI), while GDNF, NT‐3, and NT‐4 had no effect. The oculomotor neurons were immunoreactive for BDNF and the BDNF receptors p75^NTR and trkB. To determine whether BDNF may be derived from its target or may act as an autocrine or paracrine factor, in situ hybridization and deprivation studies were performed. BDNF mRNA expression was detected in eye muscles, but not in CNS sources of afferent innervation to MIII, or the oculomotor complex itself. Injection of trkB fusion proteins in the eye muscle reduced BDNF immunoreactivity in the innervating motoneurons. These data indicate that BDNF trophic support for the oculomotor neurons was derived from their target. © 1999 John Wiley & Sons, Inc. J Neurobiol 41: 295–315, 1999     

Neurotrophic agents prevent motoneuron death following sciatic nerve section in the neonatal mouse

We have examined the ability of different neurotrophic and growth factors to prevent axotomy-induced motoneuron cell death in the developing mouse spinal cord. After postnatal unilateral section of the mouse sciatic nerve, most motoneuron (MN) loss occurs in the lateral motor column of the fourth lumbar segment (L4). Significant axotomy-induced cell death occurred after surgery performed on or before postnatal day (PN) 5. In contrast, no significant cell loss was found when axotomy was performed after PN10. Axotomy on PN2 or PN5 resulted in a 44% loss of L4 motoneurons by 7 days, and a 66% loss of motoneurons by 10 days postsurgery. Implantation of gelfoam presoaked in various neurotrophic factors at the lesion site rescued axotomized motoneurons. Nerve growth factor (NGF), nedurotrophin-4/5 (NT-4/5) and ciliary neurotrophic factor (CNTF) rescued 20%–30% of motoneurons, whereas brain-derived neurotrophic factor (BDNF), neurotrophin-3 (NT-3), and insulin-like growth factor 1 (IGF-1) rescued virtually all motoneurons from axotomy-induced death. By contrast, platelet-derived growth factor (PDGF)-AA, PDGF-AB, basic fibroblast growth factor (bFGF), and interleukin (IL-6) were ineffective on motoneuron survival following axotomy. NGF, BDNF, NT-3, IGF-1, and CNTF also prevented axotomy-induced atrophy of surviving motoneurons. These data show that mouse lumbar motoneurons continue to be vulnerable to axotomy up to about 1 week after birth and that a number of trophic agents, including the neurotrophins, CNTF, and IGF-1, can prevent the death of these neurons following axotomy. Our studies confirm and extend previous reports on the time course of axotomy-induced mouse motoneuron death and the survival promoting effects of neurotrophic factors. 1994 John Wiley & Sons, Inc.     

Activation of Phosphatidylinositol 3-Kinase, but Not Extracellular-Regulated Kinases, Is Necessary to Mediate Brain-Derived Neurotrophic Factor-Induced Motoneuron Survival

Chick embryo spinal cord motoneurons develop a trophic response to some neurotrophins when they are maintained in culture in the presence of muscle extract. Thus, after 2 days in culture, brain-derived neurotrophic factor (BDNF) promotes motoneuron survival. In the present study we have analyzed the intracellular pathways that may be involved in the BDNF-induced motoneuron survival. We have observed that BDNF activated the extracellular-regulated kinase (ERK) mitogen-activated protein (MAP) kinase and the phosphatidylinositol (PI) 3-kinase pathways. To examine the contribution of these pathways to the survival effect triggered by BDNF, we used PD 98059, a specific inhibitor of MAP kinase kinase, and LY 294002, a selective inhibitor of PI 3-kinase. PD 98059, at doses that significantly reduced the phosphorylation of ERKs, did not show any prominent effect on neuronal survival. However, LY 294002 at doses that inhibited the phosphorylation of Akt, a down-stream element of the PI 3-kinase, completely abolished the motoneuron survival effects of BDNF. Moreover, cell death triggered by LY 294002 treatment exhibited features similar to those observed after muscle extract deprivation. Our results suggest that the PI 3-kinase pathway plays an important role in the survival effect triggered by BDNF on motoneurons, whereas activation of the ERK MAP kinase pathway is not relevant.     

Developmental alteration of nerve injury induced glial cell line-derived neurotrophic factor (GDNF) receptor expression is crucial for the determination of injured motoneuron fate

Axotomy-induced neuronal death occurs in neonatal motoneurons, but not in adult rat. Here we demonstrated that during the course of postnatal development, nerve injury induced down-regulation of the glial cell line-derived neurotrophic factor (GDNF) receptor GFRalpha1 in axotomized hypoglossal motoneurons of rat are gradually converted to the adult up-regulation pattern of response. The compensatory expression of GFRalpha1 specifically in the injured motoneurons of neonates by adenovirus succeeded in rescuing the injured neurons without an application of growth factors. To the contrary, the nuclear antisense RNA for GFRalpha1 expression accelerates the axotomy-induced neuronal death in pups. These findings suggest that the receptor expression response after nerve injury is critical for the determination of injured motoneuron fate.     

Conditional gene ablation of Stat3 reveals differential signaling requirements for survival of motoneurons during development and after nerve injury in the adult.

Members of the ciliary neurotrophic factor (CNTF)/leukemia inhibitory factor (LIF)/cardiotrophin gene family are potent survival factors for embryonic and lesioned motoneurons. These factors act via receptor complexes involving gp130 and LIFR-beta and ligand binding leads to activation of various signaling pathways, including phosphorylation of Stat3. The role of Stat3 in neuronal survival was investigated in mice by Cre-mediated gene ablation in motoneurons. Cre is expressed under the neurofilament light chain (NF-L) promoter, starting around E12 when these neurons become dependent on neurotrophic support. Loss of motoneurons during the embryonic period of naturally occurring cell death is not enhanced in NF-L-Cre; Stat3(flox/KO) mice although motoneurons isolated from these mice need higher concentrations of CNTF for maximal survival in culture. In contrast, motoneuron survival is significantly reduced after facial nerve lesion in the adult. These neurons, however, can be rescued by the addition of neurotrophic factors, including CNTF. Stat3 is essential for upregulation of Reg-2 and Bcl-xl expression in lesioned motoneurons. Our data show that Stat3 activation plays an essential role for motoneuron survival after nerve lesion in postnatal life but not during embryonic development, indicating that signaling requirements for motoneuron survival change during maturation.     

Differential effects of the trophic factors BDNF, NT-4, GDNF, and IGF-I on the isthmo-optic nucleus in chick embryos

The isthmo-optic nucleus (ION) of chick embryos is a model system for the study of retrograde trophic signaling in developing CNS neurons. The role of brain-derived neurotrophic factor (BDNF) is well established in this system. Recent work has implicated neurotrophin-4 (NT-4), glial cell line-derived neurotrophic factor (GDNF), and insulin-like growth factor I (IGF-I) as additional trophic factors for ION neurons. Here it was examined in vitro and in vivo whether these factors are target-derived trophic factors for the ION in 13- to 16-day-old chick embryos. Unlike BDNF, neither GDNF, NT-4, nor IGF-I increased the survival of ION neurons in dissociated cultures identified by retrograde labeling with the fluorescent tracer DiI. BDNF and IGF-I promoted neurite outgrowth from ION explants, whereas GDNF and NT-4 had no effect. Injections of NT-4, but not GDNF, in the retina decreased the survival of ION neurons and accelerated cell death in the ION. NT-4-like immunoreactivity was present in the retina and the ION. Exogenous, radiolabeled NT-4, but not GDNF or IGF-I, was retrogradely transported from the retina to the ION. NT-4 transport was significantly reduced by coinjection of excess cold nerve growth factor (NGF), indicating that the majority of NT-4 bound to p75 neurotrophin receptors during axonal transport. Binding of NT-4 to chick p75 receptors was confirmed in L-cells, which express chick p75 receptors. These data indicate that GDNF has no direct trophic effects on ION neurons. IGF-I may be an afferent trophic factor for the ION, and NT-4 may act as an antagonist to BDNF, either by competing with BDNF for p75 and/or trkB binding or by signaling cell death via p75.     

Depolarization promotes survival of ciliary ganglion neurons by BDNF-dependent and -independent mechanisms

Membrane activity upregulates brain derived neurotrophic factor (BDNF) expression to coordinately support neuronal survival in many systems. In parasympathetic ciliary ganglion (CG) neurons, activity mimicked by KCl depolarization provides nearly full trophic support. While BDNF has been considered unable to influence CG neuronal survival, we now document its expression during CG development and show that low concentrations do support survival via high-affinity TrkB receptors. Furthermore, a contribution of BDNF to activity-induced trophic support was demonstrated by showing that KCl depolarization increased BDNF mRNA and protein in, and release of BDNF from, CG neuron cultures. Application of anti-BDNF blocking antibody or mitogen activated protein kinase (MAPK) kinase inhibitor, attenuated depolarization-supported survival, implicating canonical BDNF/TrkB signaling. Ca2+-Calmodulin kinase II (CaMKII) was also required since its inhibition combined with anti-BDNF or MAPK kinase inhibitor abolished or greatly reduced the trophic effects of depolarization. Membrane activity may thus support CG neuronal survival both by stimulating release of BDNF that binds high-affinity TrkB receptors to activate MAPK and by recruiting CaMKII. This mechanism could have relevance late in development in vivo as ganglionic transmission and the effectiveness of BDNF over other growth factors both increase.     

Differential effects of the trophic factors BDNF,NT‐4, GDNF,and IGF‐I on the isthmo‐optic nucleus in chick embryos

The isthmo‐optic nucleus (ION) of chick embryos is a model system for the study of retrograde trophic signaling in developing CNS neurons. The role of brain‐derived neurotrophic factor (BDNF) is well established in this system. Recent work has implicated neurotrophin‐4 (NT‐4), glial cell line–derived neurotrophic factor (GDNF), and insulin‐like growth factor I (IGF‐I) as additional trophic factors for ION neurons. Here it was examined in vitro and in vivo whether these factors are target‐derived trophic factors for the ION in 13‐ to 16‐day‐old chick embryos. Unlike BDNF, neither GDNF, NT‐4, nor IGF‐I increased the survival of ION neurons in dissociated cultures identified by retrograde labeling with the fluorescent tracer DiI. BDNF and IGF‐I promoted neurite outgrowth from ION explants, whereas GDNF and NT‐4 had no effect. Injections of NT‐4, but not GDNF, in the retina decreased the survival of ION neurons and accelerated cell death in the ION. NT‐4–like immunoreactivity was present in the retina and the ION. Exogenous, radiolabeled NT‐4, but not GDNF or IGF‐I, was retrogradely transported from the retina to the ION. NT‐4 transport was significantly reduced by coinjection of excess cold nerve growth factor (NGF), indicating that the majority of NT‐4 bound to p75 neurotrophin receptors during axonal transport. Binding of NT‐4 to chick p75 receptors was confirmed in L‐cells, which express chick p75 receptors. These data indicate that GDNF has no direct trophic effects on ION neurons. IGF‐I may be an afferent trophic factor for the ION, and NT‐4 may act as an antagonist to BDNF, either by competing with BDNF for p75 and/or trkB binding or by signaling cell death via p75. © 2000 John Wiley & Sons, Inc. J Neurobiol 43: 289–303, 2000     

In vitro survival and differentiation of neurons derived from epidermal growth factor-responsive postnatal hippocampal stem cells: Inducing effects of brain-derived neurotrophic factor

Neural stem cells proliferate in vitro and form neurospheres in the presence of epidermal growth factor (EGF), and are capable of differentiating into both neurons and glia when exposed to a substrate. We hypothesize that specific neurotrophic factors induce differentiation of stem cells from different central nervous system (CNS) regions into particular fates. We investigated differentiation of stem cells from the postnatal mouse hippocampus in culture using the following trophic factors (20 ng/mL): brain-derived neurotrophic factor (BDNF), neurotrophin-3 (NT-3) and glial-derived neurotrophic factor (GDNF). Without trophic factors, 32% of stem cells differentiated into neurons by 4 days in vitro (DIV), decreasing to 10% by 14 DIV. Addition of BDNF (starting at either day 0 or day 3) significantly increased neuron survival (31–43% by 14 DIV) and differentiation. Morphologically, many well-differentiated neurons resembled hippocampal pyramidal neurons. 5′-Bromodeoxyuridine labeling demonstrated that the pyramidal-like neurons originated from stem cells which had proliferated in EGF-containing cultures. However, similar application of NT-3 and GDNF did not exert such a differentiating effect. Addition of BDNF to stem cells from the postnatal cerebellum, midbrain, and striatum did not induce these neuronal phenotypes, though similar application to cortical stem cells yielded pyramidal-like neurons. Thus, BDNF supports survival of hippocampal stem cell-derived neurons and also can induce differentiation of these cells into pyramidal-like neurons. The presence of pyramidal neurons in BDNF-treated hippocampal and cortical stem cell cultures, but not in striatal, cerebellar, and midbrain stem cell cultures, suggests that stem cells from different CNS regions differentiate into region-specific phenotypic neurons when stimulated with an appropriate neurotrophic factor. © 1998 John Wiley & Sons, Inc. J Neurobiol 35: 395–425, 1998     

Comparison of Trophic Factors Changes in the Hippocampal CA1 Region Between the Young and Adult Gerbil Induced by Transient Cerebral Ischemia

In the present study, we investigated neuronal death/damage in the gerbil hippocampal CA1 region (CA1) and compared changes in some trophic factors, such as brain-derived neurotrophic factor (BDNF), glial cell line-derived neurotrophic factor (GDNF) and vascular endothelial growth factor (VEGF), in the CA1 between the adult and young gerbils after 5?min of transient cerebral ischemia. Most of pyramidal neurons (89?%) were damaged 4?days after ischemia?Creperfusion (I?CR) in the adult; however, in the young, about 59?% of pyramidal neurons were damaged 7?days after I?CR. The immunoreactivity and levels of BDNF and VEGF, not GDNF, in the CA1 of the normal young were lower than those in the normal adult. Four days after I?CR in the adult group, the immunoreactivity and levels of BDNF and VEGF were distinctively decreased, and the immunoreactivity and level of GDNF were increased. However, in the young group, all of their immunoreactivities and levels were much higher than those in the normal young group. From 7?days after I?CR, all the immunoreactivities and levels were apparently decreased compared to those of the normal adult and young. In brief, we confirmed our recent finding: more delayed and less neuronal death occurred in the young following I?CR, and we newly found that the immunoreactivities of trophic factors, such as BDNF, GDNF, and VEGF, in the stratum pyramidale of the CA1 in the young gerbil were much higher than those in the adult gerbil 4?days after transient cerebral ischemia.     

Motor Enrichment and the Induction of Plasticity Before or After Brain Injury

Voluntary exercise, treadmill activity, skills training, and forced limb use have been utilized in animal studies to promote brain plasticity and functional change. Motor enrichment may prime the brain to respond more adaptively to injury, in part by upregulating trophic factors such as GDNF, FGF-2, or BDNF. Discontinuation of exercise in advance of brain injury may cause levels of trophic factor expression to plummet below baseline, which may leave the brain more vulnerable to degeneration. Underfeeding and motor enrichment induce remarkably similar molecular and cellular changes that could underlie their beneficial effects in the aged or injured brain. Exercise begun before focal ischemic injury increases BDNF and other defenses against cell death and can maintain or expand motor representations defined by cortical microstimulation. Interfering with BDNF synthesis causes the motor representations to recede or disappear. Injury to the brain, even in sedentary rats, causes a small, gradual increase in astrocytic expression of neurotrophic factors in both local and remote brain regions. The neurotrophic factors may inoculate those areas against further damage and enable brain repair and use-dependent synaptogenesis associated with recovery of function or compensatory motor learning. Plasticity mechanisms are particularly active during time-windows early after focal cortical damage or exposure to dopamine neurotoxins. Motor and cognitive impairments may contribute to self-imposed behavioral impoverishment, leading to a reduced plasticity. For slow degenerative models, early forced forelimb use or exercise has been shown to halt cell loss, whereas delayed rehabilitation training is ineffective and disuse is prodegenerative. However, it is possible that, in the chronic stages after brain injury, a regimen of exercise would reactivate mechanisms of plasticity and thus enhance rehabilitation targeting residual functional deficits.     

Anterograde axonal transport, transcytosis, and recycling of neurotrophic factors

Traditional views of neurotrophic factor biology held that trophic factors are released from target cells, retrogradely transported along their axons, and rapidly degraded upon arrival in cell bodies. Increasing evidence indicates that several trophic factors such as brain-derived neurotrophic factor (BDNF), fibroblast growth factor (FGF-2), glial cell-line derived neurotrophic factor (GDNF), insulin-like growth factor (IGF-I), and neurotrophin-3 (NT-3), can move anterogradely along axons. They can escape the degradative pathway upon internalization and are recycled for future uses. Internalized ligands can move through intermediary cells by transcytosis, presumably by endocytosis via endosomes to the Golgi system, by trafficking of the factor to dendrites or by sorting into anterograde axonal transport with subsequent release from axon terminals and uptake by second- or third-order target neurons. Such data suggest the existence of multiple “trophic currencies,” which may be used over several steps in neural networks to enable nurturing relationships between connected neurons or glial cells, not unlike currency exchanges between trading partners in the world economy. Functions of multistep transfer of trophic material through neural networks may include regulation of neuronal survival, differentiation of phenotypes and dendritic morphology, synapse plasticity, as well as excitatory neurotransmission. The molecular mechanisms of sorting, trafficking, and release of trophic factors from distinct neuronal compartments are important for an understanding of neurotrophism, but they present challenging tasks owing to the low levels of the endogeneous factors.     

Elucidating the molecular mechanisms that underlie the target control of motoneuron death

Approximately half of the motoneurons generated during normal embryonic development undergo programmed cell death. Most of this death occurs during the time when synaptic connections are being formed between motoneurons and their target, skeletal muscle. Subsequent muscle activity stemming from this connection helps determine the final number of surviving motoneurons. These observations have given rise to the idea that motoneuron survival is dependent upon access to muscle derived trophic factors, presumably through intact neuromuscular synapses. However, it is not yet understood how the muscle regulates the supply of such trophic factors, or if there are additional mechanisms operating to control the fate of the innervating motoneuron. Recent observations have highlighted target independent mechanisms that also operate to support the survival of motoneurons, such as early trophic-independent periods of motoneuron death, trophic factors derived from Schwann cells and selection of motoneurons during pathfinding. Here we review recent investigations into motoneuron cell death when the molecular signalling between motoneurons and muscle has been genetically disrupted. From these studies, we suggest that in addition to trophic factors from muscle and/or Schwann cells, specific adhesive interactions between motoneurons and muscle are needed to regulate motoneuron survival. Such interactions, along with intact synaptic basal lamina, may help to regulate the supply and presentation of trophic factors to motoneurons.