The ontogeny of specific retrograde transport of nerve growth factor by motoneurons of the brainstem and spinal cord.

Radiolabeled Nerve Growth Factor (NGF) was injected into either the mandibular process of the first visceral arch or the limb bud of chick embryos at Days 3.5-14 or Days 4-13 of incubation, respectively. Control embryos received injections of labeled cytochrome-C or labeled NGF plus an excess of unlabeled NGF. The tissues were then processed for autoradiography. The 125I-NGF was retrogradely transported by motoneurons of the trigeminal (V) motor nucleus on Days 3.5-8 of incubation, but not at later stages. Similar transport was seen in motoneurons of the spinal cord lateral motor column from Days 4-10 of incubation, but not at later stages. Sensory neurons of the V ganglion and of the dorsal root ganglia transported NGF at all injection ages. In no instance was the 125I-cytochrome-C transported by sensory or motor neurons. The injection of an excess of cold NGF along with labeled NGF resulted in no evidence of retrograde transport of the labeled NGF indicating that the transport was saturable. The time of transport by these brainstem and spinal cord motoneurons corresponds closely to the points during development at which they have been found to exhibit specific NGF binding. The present results, then, provide further evidence for a possible biological role for NGF during early developmental stages of these motoneuron populations.     

Development of substance P receptors on rat motoneurons in vitro.

Experiments were performed to examine the influence of interneuronal interactions on the expression of neurotransmitter receptors by developing mammalian CNS neurons. Receptors for the neuropeptide, substance P (SP), were assayed on embryonic rat motoneurons and other spinal cord neurons developing in vitro by the binding of 125I-SP to live neurons. Scatchard analysis showed the presence of high-affinity binding sites, and binding competition assays using SP, neurokinin A, or neurokinin B indicated that the high-affinity 125I-SP binding sites on these neurons were type NK1 tachykinin receptors, or SP receptors (SPRs). Neurons in the spinal cords of rats at Embryonic Day 14 displayed no SPRs. Cell-surface SPRs were detected on spinal cord neurons within 24 hr after they were placed in culture, however, and the level of 125I-SP binding increased for several days. SPRs were assayed on spinal motoneurons that had been identified by retrograde labeling with a fluorescent tracer, isolated in high purity by fluorescence-activated cell sorting (FACS), and maintained in culture. Motoneurons grown in isolation from other neurons developed SPRs in vitro along the same time course as neurons in heterogeneous spinal cord cultures. These results show that rat spinal motoneurons can express SPRs early in their development, and they suggest that the initial expression of SPRs by developing motoneurons does not require interaction with other neurons.     

Dental pulp cells produce neurotrophic factors, interact with trigeminal neurons in vitro, and rescue motoneurons after spinal cord injury.

Interactions between ingrowing nerve fibers and their target tissues form the basis for functional connectivity with the central nervous system. Studies of the developing dental pulp innervation by nerve fibers from the trigeminal ganglion is an excellent example of nerve-target tissue interactions and will allow specific questions regarding development of the dental pulp nerve system to be addressed. Dental pulp cells (DPC) produce an array of neurotrophic factors during development, suggesting that these proteins might be involved in supporting trigeminal nerve fibers that innervate the dental pulp. We have established an in vitro culture system to study the interactions between the dental pulp cells and trigeminal neurons. We show that dental pulp cells produce several neurotrophic factors in culture. When DPC are cocultured with trigeminal neurons, they promote survival and a specific and elaborate neurite outgrowth pattern from trigeminal neurons, whereas skin fibroblasts do not provide a similar support. In addition, we show that dental pulp tissue becomes innervated when transplanted ectopically into the anterior chamber of the eye in rats, and upregulates the catecholaminergic nerve fiber density of the irises. Interestingly, grafting the dental pulp tissue into hemisected spinal cord increases the number of surviving motoneurons, indicating a functional bioactivity of the dental pulp-derived neurotrophic factors in vivo by rescuing motoneurons. Based on these findings, we propose that dental pulp-derived neurotrophic factors play an important role in orchestrating the dental pulp innervation.     

Neuronal precursor cells in chick dorsal root ganglia: differentiation and survival in vitro

Neuronal precursor cells present in dorsal root ganglia (DRG) during early development have been previously shown to differentiate in vitro to neurons, as characterized by morphology, cell surface antigens, and electrophysiological properties (H. Rohrer, S. Henke-Fahle, T. El-Sharkawy, H. D. Lux, and H. Thoenen, 1985, Embo J. 4, 1709-1714). In the present study the conditions necessary for the initial differentiation and long-term survival of these cells were established, and the neurotransmitter phenotype of the newly differentiated neurons was analyzed. Neuronal precursor cells isolated from chick DRG at Embryonic Day 6 (E6) were found to require the presence of a polyornithine substrate coated with either laminin or fibronectin for initial neurite production and long-term survival. Neurons were unable to develop on polyornithine alone or on polyornithine coated with BSA. The survival and neurite outgrowth from neuronal precursor cells was not affected by the presence of nerve growth factor (NGF) during the first 9 hr in culture. NGF also had no effect on the proportion of cells expressing the neuron-specific Q211 antigen. However, after this initial differentiation period the neurons did require the presence of a survival factor. The neurons could be maintained for at least 6 days in culture both in the presence of NGF and in the presence of brain-derived neurotrophic factor (BDNF). At saturating concentrations of both survival factors no additive effects could be observed, indicating a complete overlap of NGF- and BDNF-responsiveness. Although the same proportion of cells survived with either NGF or BDNF during the first 3 days in culture, survival decreased in the presence of BDNF but not in the presence of NGF during the following 3 days in culture. The loss of BDNF responsiveness in vitro was also observed in vivo. After 6 days in culture about 70% of the neurons expressed substance P immunoreactivity, and approximately the same proportion was positive for myelin-associated glycoprotein immunoreactivity. The neurons did not express properties of adrenergic neurons such as tyrosine hydroxylase immunoreactivity or norepinephrine uptake. These findings indicate that the neuronal precursor cells from E6 DRG acquire the same characteristics in vitro as in their normal in vivo environment.     

The effects of nerve growth factor and dibutyryl cyclic AMP on cytoskeletal densities in cultured sensory ganglia.

The effects of nerve growth factor (NGF) and dibutyryl cyclic AMP (DBC) on the density of cytoskeletal structures in cultured dorsal root ganglia were examined using morphometric techniques. After 24 hr in culture, NGF-treated neurites were longer than either DBC-treated or control neurites. At 48 hr, neurites produced in response to NGF and DBC were of equivalent length, while controls were considerably shorter. Comparison of electron micrographs of neuritic profiles revealed some differences of area and cytoskeletal density between treatment groups. Morphometric analysis was used to determine these differences under several growth conditions, at various rates of elongation and at different neurite lengths. As shown by analysis of variance, both NGF-treated and control neurites tapered in diameter at 48 hr in vitro, while DBC-induced neurites increased in area. An increase in cytoskeletal density for all treatment groups indicated that density was not always correlated with changes in area. An increased density of microtubules as compared to neurofilaments was seen at 24 hr, with equal densities of both cytoskeletal elements present after 48 hr in vitro. Comparisons between individual groups of data indicated that NGF-treated neurites relied primarily on microtubular density at 24 hr in vitro, when NGF induced longer, faster growing neurites. At 48 hr, there was an increase in neurofilaments proximal to the explant in the presence of DBC, implying that DBC may cause increased synthesis and/or transport of these structures. A comparison of microtubule to neurofilament ratios indicated that at 24 hr, there was always a greater density of microtubules. However, after 48 hr, neurofilament density increased such that there were equivalent densities of both cytoskeletal elements, possibly due to the overall increase in length observed in each treatment group. These data imply that 1) neurites with different rates of elongation may exhibit differences in cytoskeletal density; 2) neurites of equivalent lengths may be of differing stabilities; 3) NGF and DBC produce neurites with different cytoskeletal densities, implying divergent mechanisms of neurite induction; 4) the presence or absence of NGF may be partially responsible for variations in cytoskeletal densities observed between peripheral and central processes of DRG during development.     

Neuronal survival in intact ciliary ganglia in vivo and in vitro: Ciliary neuronotrophic factor as a target surrogate

Ciliary neuronotrophic factor (CNTF) requirements for neuronal survival in the intact ciliary ganglion (CG) have been investigated in organ culture. Exogenous CNTF was not essential for neuronal survival until embryonic Day 8. Three-day cultures from 5-day ganglia were similar with or without CNTF, showing numerous neurons and extensive neuritic development. In 3-day cultures from 8-day-old ganglia, however, no neurons survived without CNTF, and the ganglia contained only nonneuronal cells and cell debris. Similar ganglia cultured with CNTF contained many neurons, surrounded by nonneuronal cells, and abundant neuritic processes. Morphologic maturation of the neurons was less advanced in CNTF-supported ganglia than in their in vivo counterparts.     

Nerve growth factor-induced stimulation of dorsal root ganglion/spinal cord co-grafts in oculo: enhanced survival and growth of CGRP-immunoreactive sensory neurons

Intraocular co-grafts of rat fetal spinal cord and dorsal root ganglia were used to examine the enhanced survival, growth, and differentiation of sensory neurons by nerve growth factor. E14 lumbar spinal segments were implanted into the anterior eye chamber of capsaicin-pretreated rats. Two weeks later, an E14 dorsal root ganglion was implanted beside the spinal cord graft. Nerve growth factor or vehicle was injected weekly for 4 weeks into the anterior eye chamber. Co-grafts were examined weekly and, at 6 weeks, processed for calcitonin gene-related peptide (CGRP) immunofluorescence. No differences in overall size were determined for the grafts. Co-grafts treated with nerve growth factor contained many more CGRP neurons (19.4 cells/20 microm) that were significantly larger (mean 764 microm2) than neurons from control co-grafts (8.6 cells/20 microm; mean 373 microm2). In co-grafts treated with nerve growth factor, CGRP-immunoreactive fibers were extensive in the dorsal root ganglion, adjacent iris, and spinal cord compared to control co-grafts. A few CGRP-positive motoneurons were observed in the spinal cord, but no differences in number or size of motoneurons were found. The current report demonstrates that spinal cord and dorsal root ganglia can be co-grafted in oculo for long periods of time. Many dorsal root ganglion neurons survive and send peripheral processes into the iris and central processes into the spinal cord under the influence of exogenous nerve growth factor. The intraocular graft paradigm can be of use to further examine the role of neurotrophic factors in regulating or modulating dorsal root ganglion and spinal cord neurons.     

Biochemical and cytospectrophotometric analysis of the extraction of RNA from spinal cord cell structures]

By means of two-wavelength spectrophotometry, according to Tsanev and Markov, a stability of RNA content has been demonstrated in rabbit spinal cord sections treated with cold perchloric acid: it was only after 18 and particularly 48 hr incubation of the section in a 16% perchloric acid solution that the total tissue RNA began to be extracted. Cytospectrophotometrical study of the motoneurons of spinal cord anterior horns and perineuronal glial cells in gallocyanin -- chrome alum stained sections has shown a rapid loss of RNA under effect of the cold perchloric acid: as early as after a 2 hr treatment, about 2/3 of the whole cellular RNA was extracted from the motoneurons, while about 1/2 from their glial satellite cells. Hydrolysis of the rest of RNA was found out in the neurons and in the neuroglia only after a 18 hr extraction with the perchloric acid. Similarities and differences in the features of neuronal and glial RNA are discussed.     

Cholinergic differentiation factor (CDF/LIF) promotes survival of isolated rat embryonic motoneurons in vitro.

We present evidence that the cholinergic differentiation factor (CDF), originally purified from cardiac and skeletal muscle cell-conditioned medium and found to be identical to leukemia inhibitory factor (LIF), promotes survival of embryonic day 14 rat motoneurons in vitro. These neurons were retrogradely labeled with the fluorescent tracer Dil and enriched on a density gradient or purified to homogeneity by fluorescence-activated cell sorting. Subnanomolar concentrations of CDF/LIF supported the survival of 85% of the motoneurons that would have died between days 1 and 4 of culture. The enhanced survival was accompanied by a 4-fold increase in choline acetyltransferase (ChAT) activity per culture. CDF/LIF also increased ChAT activity in dorsal spinal cord cultures, but had no detectable effect on ChAT levels in septal or striatal neuronal cultures. For comparison, other neurotrophic molecules were tested on motoneuron cultures. Ciliary neurotrophic factor had effects on motoneuron survival similar to those of CDF/LIF, whereas basic fibroblast growth factor was somewhat less effective. Nerve growth factor had no effect on the survival of rat motoneurons.     

Quantitative in vitro studies on the nerve growth factor (NGF) requirement of neurons: I. Sympathetic neurons

Quantitative studies on the nerve growth factor (NGF) requirement of chick embryo sympathetic neurons in dissociated cell culture revealed the following. (i) The minimum concentration of 2.5 S NGF required for survival of maximal numbers of neurons is about 0.5 ng/ml (～2 × 10^?11M). In culture, this concentration of NGF appears not to be stable for more than 24 hr. Long-term neuronal maintenance with medium changes twice weekly requires a minimum of 5 ng/ml of NGF. (ii) At 24 hr after plating in medium containing 10% fetal bovine serum, neuronal survival is less than optimal at NGF concentrations above 5 ng/ml; in medium with 5% horse serum, survival is constant with up to 5000 ng/ml of NGF. (iii) Survival of neurons after 1 week in culture was less than optimal at NGF concentrations greater than 50 ng/ml, even in medium containing horse serum. (iv) No correlation was observed between the level of NGF (0.5–500 ng/ml) and the estimated neuronal somatic volumes up to 1 month in vitro. (v) Withdrawal of NGF, even after 4 weeks of culture, resulted in degeneration of nerve cell bodies and processes.     

谷氨酸转运抑制剂对器官型培养脊髓片的影响

观察谷氨酸转运体抑制剂苏一羟天冬氨酸(Threo-hydroxyaspartate,THA)对器官型培养的脊髓片的影响,探讨谷氨酸在运动神经元损伤中的作用。取出生后8天乳鼠的腰段脊髓组织切片做脊髓器官型培养,在培养液中加入不同浓度THA(50μmol／L、100μmol／L、5001μmol／L),用神经元的特异性免疫组化染色剂SMI-32,非磷酸化神经丝标记物,对脊髓腹角α运动神经元进行鉴定,用单克隆抗钙网膜蛋白(calretinin)抗体对背角中间神经元进行记数,测定培养液中乳酸脱氢酶(LDH)的含量,并与对照组比较。结果显示对照组α运动神经元数目恒定,THA可以引起剂量依赖性的培养液中LDH含量增高和α运动神经元数目减少,而脊髓背角的中间神经元损伤相对较轻,其中THA100μmol／L组在体外培养4周后出现类似于肌萎缩侧索硬化(ALS)的病理改变：α运动神经元数目较对照组明显减少,而脊髓背角的中间神经元数目无显著变化。细胞外谷氨酸增高主要对运动神经元造成损伤,脊髓运动神经元较感觉神经元对谷氨酸的兴奋毒作用更加敏感。     

Growth factor dependent cholinergic function and survival in primary mouse spinal cord cultures

In primary embryonic spinal cord cultures, synaptic transmission can be conveniently studied by monitoring radiolabeled neurotransmitter release or by recording of electrophysiological responses. However, while the mature spinal cord contains an appreciable number of cholinergic motoneurons, cultures of embryonic spinal cord have a paucity of these neurons and release little or no acetylcholine upon stimulation. To determine whether the proportion of cholinergic neurons in primary mouse spinal cord cultures can be augmented, the effects of several classes of growth factors were examined on depolarization- and Ca(2+)-evoked release of choline/acetylcholine (Ch/ACh). In the absence of growth factors, little or no evoked release of radiolabeled Ch/ACh could be demonstrated. Media supplemented with brain-derived neurotrophic factor (BDNF), ciliary neurotrophic factor (CNTF) or basic fibroblast growth factor (bFGF) were examined for their ability to preserve the population of neurons in culture. CNTF was found to increase the number of surviving neurons and to enhance the release of radiolabeled Ch/ACh; the other factors were without effect. The action of CNTF was transient, and the neuronal population decreased to levels observed in cultures lacking growth factor after 20 days in vitro. The correlation between enhanced neuron survival and increased Ch/ACh release suggests that CNTF protected cholinergic neurons, albeit transiently, from cell death.     

Developmental motoneuron cell death and neurotrophic factors

During the development of higher vertebrates, motoneurons are generated in excess. In the lumbar spinal cord of the developing rat, about 6000 motoneurons are present at embryonic day 14. These neurons grow out axons which make contact with their target tissue, the skeletal muscle, and about 50% of the motoneurons are lost during a critical period from embryonic day 14 until postnatal day 3. This process, which is called physiological motoneuron cell death, has been the focus of research aiming to identify neurotrophic factors which regulate motoneuron survival during this developmental period. Motoneuron cell death can also be observed in vitro when the motoneurons are isolated from the embryonic avian or rodent spinal cord. These isolated motoneurons and other types of primary neurons have been a useful tool for studying basic mechanisms underlying neuronal degeneration during development and under pathophysiological conditions in neurodegenerative disorders. Accumulating evidence from such studies suggests that some specific requirements of motoneurons for survival and proper function may change during development. The focus of this review is a synopsis of recent data on such specific mechanisms.     

Human Skeletal Muscle Cells Synthesise a Neuronotrophic Factor Reactive with Spinal Neurons

Retrograde trophic influences originating in the skeletal musculature have been postulated to be involved in regulating survival and differentiation of embryonic motor neurons and reactive terminal sprouting of mature motor fibres. We have previously described the use of a quantitative immunoassay for neurofilament protein to bioassay in vitro the cell-type-specific neuronotrophic activity of nerve growth factor (NGF) on sensory ganglion neurons. In the present study, the effect of media conditioned by adult human muscle cells (MCM) on the in vitro development of chicken spinal neurons has been studied using a similar approach. Significant increases in neurofilament protein levels in 7-day chicken embryonic spinal cord cultures were found with doses of MCM protein as low as 0.4 microgram/ml, with a dose-response relationship yielding maximal and half-maximal effects at 4 and 1 microgram/ml, respectively. Maximal increases in neurofilament protein levels were associated with an approximate two-fold increase in neuronal cell survival. MCM also induced increases in choline acetyltransferase activity in chick spinal cord cultures. In both the absence and presence of NGF, MCM did not increase neurofilament protein expression in primary cultures of sensory neurons.     

Placodal sensory neurons in culture: nodose ganglion neurons are unresponsive to NGF, lack NGF receptors but are supported by a liver-derived neurotrophic factor

Explant and dissociated neuron-enriched cultures of nodose ganglia (inferior or distal sensory ganglion of the Xth cranial nerve) were established from chick embryos taken between embryonic Day 4 (E4) and Day 16 (E16). The response of each type of culture to nerve growth factor (NGF) was examined over this developmental range. At the earliest ages taken (E4-E6), NGF elicited modest neurite outgrowth from ganglion explants cultured in collagen gel for 24 hr, although the effect of NGF on ganglia taken from E4 chicks was only marginally greater than spontaneous neurite extension from control ganglia of the same developmental age. The response of nodose explants to NGF was maximal at E6-E7, but declined to a negligible level in ganglia taken from E9-E10 or older chick embryos. In dissociated neuron-enriched cultures, nodose ganglion neurons were unresponsive to NGF throughtout the entire developmental age range between E5 and E12. In contrast to the lack of effect of NGF, up to 50% of nodose ganglion neurons survived and produced extensive neurites in dissociated cultures, on either collagen- or polylysine-coated substrates, in the presence of extracts of late embryonic or early posthatched chick liver (E18-P7). Antiserum to mouse NGF did not block the neurotrophic activity of chick (or rat or bovine) liver extracts. Whether cultured with chick liver extract alone or with chick liver extract plus NGF, nodose ganglion neurons taken from E6-E12 chick embryos and maintained in culture for 2 days were devoid of NGF receptors, as assessed by autoradiography of cultures incubated with 125I-NGF. Under similar conditions 70-95% of spinal sensory neurons (dorsal root ganglion--DRG) were heavily labeled. 2+     

Placode and neural crest-derived sensory neurons are responsive at early developmental stages to brain-derived neurotrophic factor

The response of embryonic chick nodose ganglion (neural placode-derived) and dorsal root ganglion (neural crest-derived) sensory neurons to the survival and neurite-promoting activity of brain-derived neurotrophic factor (BDNF) was studied in culture. In dissociated, neuron-enriched cultures established from chick embryos between Day 6 (E6) and Day 12 (E12) of development, both nodose ganglion (NG) and dorsal root ganglion (DRG) neurons were responsive on laminin-coated culture dishes to BDNF. In the case of NG, BDNF elicited neurite outgrowth from 40 to 50% of the neurons plated at three embryonic ages; E6, E9, and E12. At the same ages, nerve growth factor (NGF) alone or in combination with BDNF, had little or no effect upon neurite outgrowth from NG neurons. The response of NG neurons to BDNF was dose dependent and was sustainable for at least 7 days in culture. Surprisingly, in view of a previous study carried out using polyornithine as a substrate for neuronal cell attachment, on laminin-coated dishes BDNF also sustained survival and neurite outgrowth from a high percentage (60-70%) of DRG neurons taken from E6 embryos. In marked contrast to NG neurons, the combined effect of saturating levels of BDNF and NGF activity on DRG neurons was greater than the effect of either agent alone at all embryonic ages studied. Under similar culture conditions, BDNF did not elicit survival and neurite outgrowth from paravertebral chain sympathetic neurons or parasympathetic ciliary ganglion neurons. We propose that primary sensory neurons, regardless of their embryological origin, are responsive to a "central-target" (CNS) derived neurotrophic factor--BDNF, while they are differentially responsive to "peripheral-target"-derived growth factors, such as NGF, depending on whether the neurons are of neural crest or placodal origin.     

Enrichment of spinal cord cell cultures with motoneurons

Spinal cord cell cultures contain several types of neurons. Two methods are described for enriching such cultures with motoneurons (defined here simply as cholinergic cells that are capable of innervating muscle). In the first method, 7-day embryonic chick spinal cord neurons were separated according to size by 1 g velocity sedimentation. It is assumed that cholinergic motoneurons are among the largest cells present at this stage. The spinal cords were dissociated vigorously so that 95-98% of the cells in the initial suspension were isolated from one another. Cells in leading fractions (large cell fractions: LCFs) contain about seven times as much choline acetyltransferase (CAT) activity per unit cytoplasm as do cells in trailing fractions (small cell fractions: SCFs). Muscle cultures seeded with LCFs develop 10-70 times as much CAT as cultures seeded with SCFs and six times as much CAT as cultures seeded with control (unfractionated) spinal cord cells. More than 20% of the large neurons in LCF-muscle cultures innervate nearby myotubes. In the second method, neurons were gently dissociated from 4-day embryonic spinal cords and maintained in vitro. This approach is based on earlier observations that cholinergic neurons are among the first cells to withdraw form the mitotic cycle in the developing chick embryo (Hamburger, V. 1948. J. Comp. Neurol. 88:221-283; and Levi-Montalcini, R. 1950. J. Morphol. 86:253-283). 4-Day spinal cord-muscle cultures develop three times as much CAT as do 7-day spinal cord-muscle plates, prepared in the same (gentle) manner. More than 50% of the relatively large 4-day neurons innervate nearby myotubes. Thus, both methods are useful first steps toward the complete isolation of motoneurons. Both methods should facilitate study of the development of cholinergic neurons and of nerve-muscle synapse formation.     

Vascular endothelial growth factor protects spinal cord motoneurons against glutamate-induced excitotoxicity via phosphatidylinositol 3-kinase

Amyotrophic lateral sclerosis (ALS) is a neurodegenerative disease characterized by the selective death of motoneurons. Recently, vascular endothelial growth factor (VEGF) has been identified as a neurotrophic factor and has been implicated in the mechanisms of pathogenesis of ALS and other neurological diseases. The potential neuroprotective effects of VEGF in a rat spinal cord organotypic culture were studied in a model of chronic glutamate excitotoxicity in which glutamate transporters are inhibited by threohydroxyaspartate (THA). Particularly, we focused on the effects of VEGF in the survival and vulnerability to excitotoxicity of spinal cord motoneurons. VEGF receptor-2 was present on spinal cord neurons, including motoneurons. Chronic (3 weeks) treatment with THA induced a significant loss of motoneurons that was inhibited by co-exposure to VEGF (50 ng/mL). VEGF activated the phosphatidylinositol 3-kinase/Akt (PI3-K/Akt) signal transduction pathway in the spinal cord cultures, and the effect on motoneuron survival was fully reversed by the specific PI3-K inhibitor, LY294002. VEGF also prevented the down-regulation of Bcl-2 and survivin, two proteins implicated in anti-apoptotic and/or anti-excitotoxic effects, after THA exposure. Together, these findings indicate that VEGF has neuroprotective effects in rat spinal cord against chronic glutamate excitotoxicity by activating the PI3-K/Akt signal transduction pathway and also reinforce the hypothesis of the potential therapeutic effects of VEGF in the prevention of motoneuron degeneration in human ALS.     

Early regional variations in motoneuron numbers arise by differential proliferation in the chick embryo spinal cord

Regional differences in the number of motoneurons in the spinal cord of the chick are thought to arise developmentally by region-specific cell death and cell migration. In this way, a numerically homogeneous motor column throughout the spinal cord is believed to be molded into the adult pattern. Region-specific differences in proliferation are not thought to play a significant role in this process. By counting motoneurons in serial sections throughout the rostral-caudal extent of the spinal cord on Embryonic Day 4 in the chick, we have found that the numerical variations in motoneurons in different spinal cord regions are already foreshadowed by this stage, which is before the onset of both cell death and the secondary migration of neurons out of the motor column. These results indicate that although nonproliferative events may contribute to the later regional variations in motoneuron numbers, the initial differences themselves are created early on by regionally specific proliferative events.