Development of interneurons with ipsilateral projections in embryonic rat spinal cord

Considerable progress has been made in recent years in identifying molecules with restricted expression in mammalian spinal cord at early developmental stages. However, the significance of the different expression patterns for most of these molecules is nuclear because so little is known about the development of various classes of spinal interneurons. Recently, we have characterized the development of rat spinal cord interneurons with an axon that crosses in the ventral commissure (Silos-Santiago and Snider, J. Comp. Neurol., 325:514, 1992). In the current study, we describe the morphological development of ipsilaterally projecting spinal interneurons in laminae V–VIII of the thoracic spinal cord. These neurons were labelled by retrograde lateral diffusion of DiI after crystals were placed in various locations in the embryonic thoracic cord. By E14, approximately 48 hours after the first interneurons are generated, eight different groups of ipsilateral interneurons are present in the spinal cord. By E15, these groups of ipsilateral interneurons have reached distinct locations within the gray matter. Even at this early stage, different groups of cells have elaborated characteristic dendritic arborizations. By E19, at least 17 different types of ipsilateral interneurons can be identified on the basis of location and dendritic morphology. In general, ipsilateral interneurons are located more dorsally and laterally than commissural interneurons at all stages of embryonic development. Furthermore, in comparison with commissural neurons, fewer ipsilateral interneurons have dendritic arbors with a mediolateral orientation in the transverse plane. This work demonstrates that rat embryonic spinal cord contains a large number of morphologically distinct classes of interneurons that extend axons into the ipsilateral lateral funiculus. These neurons can be distinguished from commissural neurons on the basis of location and morphology. These results, taken together with those from our previous study, provide a framework for the localization of gene expression to different classes of spinal interneurons at early developmental stages. © 1994 Wiley-Liss, Inc.     

Embryonic GABAergic spinal commissural neurons project rostrally to mesencephalic targets

Although spinal commissural neurons serve as a model system for studying the mechanisms that underlie axonal pathfinding during development, little is known about their synaptic targets. Previously we identified a group of ventromedially located commissural neurons in rat spinal cord that are gamma-aminobutyric acid (GABA)-ergic and express L1 CAM on their axons. In this study, serial sagittal sections of embryos (E12-15) were processed for glutamic acid decarboxylase (GAD)-65 and L1 immunocytochemistry and showed labeled commissural axons coursing rostrally within the ventral marginal zone. Both GAD65- and L1-positive axons extended rostrally out of the spinal cord into the central part of the medulla and then into the midbrain. GAD65-positive axons branched and ended abruptly within the lateral midbrain. To determine the targets of these ventral commissural neurons, embryos (E13-15) were injected with DiI into the ventromedial spinal cord. At all three ages, DiI-labeled axons projected rostrally in the contralateral ventral marginal zone, turned into the central medulla, and then traveled to the midbrain. DiI-labeled axons appeared to terminate in the lateral midbrain by branching into small, punctate structures. In reciprocal experiments, DiI injected into the lateral midbrain identified an axon pathway that coursed through the brainstem, into the spinal cord ventral marginal zone, and then filled cell bodies in the contralateral ventromedial spinal cord. A spatial and temporal coincidence was apparent between the GAD65/L1- and the DiI-labeled pathways. Together these findings suggest that some GABAergic commissural neurons are early projection neurons to midbrain targets and most likely represent a spinomesencephalic pathway to the midbrain reticular formation.     

Development changes in the distribution of gamma-aminobutyric acid-immunoreactive neurons in the embryonic chick lumbosacral spinal cord

The development of γ-aminobutyric acid (GABA)-immunoreactive neurons was investigated in the embryonic and posthatch chick lumbosacral spinal cord by using pre- and postembedding immunostaining with an anti-GABA antiserum. The first GABA-immunoreactive cells were detected in the ventral one-half of the spinal cord dorsal to the lateral motor exception of the lateral motor column, appeared throughout the entire extent of the ventral one-half of the spinal gray matter by E6. Thereafter, GABA-immunoreactive neurons extended from ventral to dorsal regions. Stained perikarya first appeared at E8 and then progressively accumulated in the dorsal horn, while immunoreactive neurons gradually declined in the ventral horn. The general pattern of GABA immunoreactivity characteristic of mature animals had been achieved by E12 and was only slightly altered afterwards. In the dorsal horn, most of the stained neurons were observed in laminae I–III, both at the upper (LS 1–3) and at the lower (LS 5–7) segments of the lumbosacral spinal cord. In the ventral horn, the upper and lower lumbosacral segments showed marked differences in the distribution of stained perikarya. GABAergic neurons were scattered in a relatively large region dorsomedial to the lateral motor column at the level of the upper lumbosacral segments, whereas they were confined to the dorsalmost region of lamina VII at the lower segments. The early expression of GABA immunoreactivity may indicate a trophic and synaptogenetic role for GABA in early phases of spinal cord development. The localization of GABAergic neurons in the ventral horn and their distribution along the rostrocaudal axis of the lumbosacral spinal cord coincide well with previous physiological findings, suggesting that some of these GABAergic neurons may be involved in neural circuits underlying alternating rhythmic motor activity of the embryonic chick spinal cord. © 1994 Wiley-Liss, Inc.     

Characterization of nerve growth factor binding to embryonic rat spinal cord neurons

The binding of iodinated beta-nerve growth factor, [125I]-NGF, to embryonic (E16) rat spinal cord cells, was investigated to characterize the binding properties and cellular distribution of nerve growth factor receptors. Spinal cord cells prepared without trypsin yielded two classes of NGF binding sites with Kd's of 3 x 10(-11) M and 4 x 10(-9) M. Fractionation of the cells by discontinuous gradients composed of 8%, 12%, and 17% metrizamide was used to separate motoneurons from other cell types. The motoneuron enriched fraction (8% metrizamide) contained approximately 10% of the cells and 64% of the choline acetyltransferase (ChAT) activity. In contrast, the 12% metrizamide fraction contained most (51%) of the cells and 36% of the ChAT activity, while the 17% metrizamide fraction contained the remainder of the cells and negligible amounts of ChAT activity. Characterization of [125I]-NGF binding to each metrizamide fraction showed that the motoneuron-enriched fraction exhibited both high and low affinity binding sites, while the other metrizamide fractions exhibited only the low affinity binding sites. These findings indicate that although low affinity NGF receptors appear to be relatively evenly distributed amongst embryonic rat spinal cord cells, high affinity NGF receptors are found primarily on motoneurons.     

Identification of spinal neurons in the embryonic and larval zebrafish.

Previous studies indicated that the developing fish spinal cord was a simple system containing a small number of distinguishable neuronal cell types (Eisen et al., Nature 320:269-271, '86; Kuwada, Science, 233:740-746, '86). To verify this we have characterized the cellular anatomy of the spinal cord of developing zebrafish in order to determine the number, identities, and organization of the spinal neurons. Spinal neurons were labeled by intracellular dye injections, application of an axonal tracer dye to all or subsets of the axonal tracts, and application of antibodies which recognize embryonic neurons. We found that nine classes of neurons could be identified based on soma size and position, pattern of dendrites, axonal trajectory, and time of axonogenesis. These are two classes of axial motor neurons, which have been previously characterized (Myers, J. Comp. Neurol. 236:555-561, '85), one class of sensory neurons, and six classes of interneurons. One of the interneuron classes could be subclassified as primary and secondary based on criteria similar to those used to classify the axial motor neurons into primary and secondary classes. The early cord (18-20 hours) is an extremely simple system and contains approximately 18 lateral cell bodies per hemisegment, which presumably are post-mitotic cells. By this stage, five of the neuronal classes have begun axonogenesis including the primary motor neurons, sensory neurons, and three classes of interneurons. By concentrating on these early stages when the cord is at its simplest, pathfinding by growth cones of known identities can be described in detail. Then it should be possible to test many different mechanisms which may guide growth cones in the vertebrate central nervous system (CNS).     

Characterization of commissural interneurons in the lumbar region of the neonatal rat spinal cord

Neurons with axons that extend to the contralateral side of the spinal cord—commissural interneurons (CINs)—coordinate left/right alternation during locomotion. Little is known about the organization of CINs in the mammalian spinal cord. To determine the numbers, distribution, dendritic morphologies, axonal trajectories, and termination patterns of CINs located in the lumbar spinal cord of the neonatal rat, several different retrograde and anterograde axonal tracing paradigms were performed with fluorescent dextran amines and the lipophilic tracer 1,1′-dioctadecyl-3,3,3′,3′-tetramethylindocarbocyanine perchlorate (DiI). CINs with ascending (aCINs) and descending (dCINs) axons were labeled independently. The aCINs and dCINs occupied different but overlapping domains within the transverse plane. The aCINs were clustered into four recognizable groups, and the dCINs were clustered into two recognizable groups. All dCINs and most aCINs were located within the gray matter, with somata ranging from 10–30 μm in diameter and with large, multipolar dendritic trees. One group of aCINs was located outside the gray matter along the dorsal and dorsolateral margin and had dendrites that were nearly confined to the dorsolateral surface. All CIN axons traversed the ventral commissure at right angles to the midline. CIN axons coursed up to six or seven segments rostrally and/or caudally in the ventral and ventrolateral white matter and gave off collaterals over a shorter range, predominantly to the ventral gray matter. These findings show that the lumbar spinal cord of the neonatal rat contains substantial numbers of CINs with axon projections and collateral ranges spanning several segments and that CINs projecting rostrally vs. caudally have different distributions in the transverse plane. The study provides an anatomical framework for future electrophysiological studies of the spinal neuronal circuits underlying locomotion in mammals. J. Comp. Neurol. 403:332–345, 1999. © 1999 Wiley-Liss, Inc.     

Intraspinal transplantation of embryonic spinal cord tissue in neonatal and adult rats

Fetal rat spinal cord tissue was obtained on gestational day 14 (E14) and transplanted into 2-4-mm-long intraspinal cavities produced by partial spinal cord lesions in adult and neonatal rats. At regular post-transplantation intervals, light and electron microscopy, autoradiographic demonstration of tritiated thymidine labelling, and immunocytochemical localization of glial fibrillary acidic protein (GFAP) were used to identify surviving donor tissues and to study their differentiation and extent of fusion with recipient spinal cords. In some experiments, wheat germ agglutinin-conjugated horseradish peroxidase (WGA-HRP) was also employed to examine whether neurons within the grafts projected axons into the host spinal cord and vice versa. Lastly, immunocytochemistry was used to determine whether any supraspinal serotoninergic (5-HT) axons from the host extended into the transplants. Over 80% of the grafts survived in lesions of both the neonatal and adult rat spinal cord for periods of 1-16 months (duration of experiment), and considerable maturation of donor tissue was evidenced, which even included the appearance of some topographical features of the normal spinal cord. Many of the transplants extended the entire length of the lesion, and were often closely apposed to the injured surfaces of the recipient spinal cords without an intervening dense glial scar. At post-transplantation intervals of 2-4 months, injection of WGA-HRP into the host spinal cord (5 mm from the transplant in adult animals or as much as 20 mm in neonatal recipients) demonstrated retrogradely labelled neurons and anterogradely labelled axons in the grafts. Likewise, injecting WGA-HRP into transplants in adult recipients resulted in labelling of neurons in adjacent segments of the host spinal cord; some labelled axons, derived from donor neurons, were also present in neighboring spinal gray matter. Finally, immunocytochemistry revealed 5-HT-like immunoreactive fibers in transplants that had been prelabelled with tritiated thymidine. These observations demonstrate the potential of embryonic spinal cord transplants to replace damaged intraspinal neuronal populations and to restore some degree of anatomical continuity between the isolated rostral and caudal stumps of the injured mammalian spinal cord.     

Development of mouse spinal cord in tissue culture: IV. Effects of embryonic extracts on neuron formation and migration

Possible influences upon patterns of neurogenesis expressed in vitro were examined quantitatively by the use of microfragment cultures of embryonic day 10 mouse neural tube. Crude extracts were prepared either from whole embryos (day 13 or 15 of gestation) or from embryonic brains (day 18 of gestation) and added to the culture medium for the first 10 days of culturing. Neuronal outgrowth zones surrounding individual microfragments were reduced in area (indicating restricted neuronal migration) and in number of neurons present (indicating restricted production of neurons) following treatment with either of the extracts. The severity of reductions observed were related to the developmental age of embryonic tissue used for preparing the extract, as greatest reduction resulted from addition of embryonic day 18 brain extracts and to concentration employed, higher doses further restricting neuronal outgrowth. By increasing the concentrations of extract the proportional number of large-sized neurons forming the outgrowth zones became greater relative to the small neuron contribution, indicating an enhanced survival for this neuronal population. The formation and migration of astroglial precursor cells was not affected by the addition of any of the extracts. The number of neurons remaining within the original portions of neural tube microfragments was not significantly altered following culturing in the presence of embryonic extract. This suggested that the reduction in neuron number in the outgrowth zone actually reflected a decreased neuron production and was not simply the result of a retention of neurons within the remaining portion of the microfragment. The results suggest the presence of substances within mouse embryos that have regulatory effects on aspects of development of the central nervous system. Indications are that survival and maturation of postmitotic neuroblasts are promoted in vitro while the formation of additional neuronal progenitor cells may be partially inhibited by the addition of embryonic mouse extracts to the medium. We propose that an endogenous negative feedback mechanism may be involved in the coordination of patterns of neurogenesis.     

Mechanosensitive neurons in the spinal cord of the lamprey

‘Fictive locomotion’ in the lamprey in vitro spinal cord-notochord preparation can be entrained by side to side movements of the spinal cord-notochord which mimic swimming movements even after transection of dorsal and ventral roots. This study provides direct evidence of mechonosensitive neurons intrinsic to the spinal cord. Neurons with axons located in the lateral aspect of the spinal cord discharge in response to moderate bending movements of the spinal cord. Movements of this amplitude will inevitably occur during normal swimming.     

Early axon and dendritic outgrowth of spinal accessory motor neurons studied with DiI in fixed tissues

We have utilized lateral diffusion of DiI in fixed tissues (Godement et al., '87: Development 101: 697-713) to study early axon and dendritic outgrowth of spinal accessory motor neurons in embryonic rats. Crystals were placed in the central canal of the cervical spinal cord near the ventral commissure in order to label growing accessory axons anterogradely and on the spinal accessory nerve to label somata and dendrites retrogradely. Animals were studied on E11-E13. We show here that it is possible to stain axonal and dendritic processes from the earliest stages of motor neuron differentiation by using DiI. Our results demonstrate that, unlike axons of other cervical motor neurons, accessory axons traverse the lateral region of the embryonic cord, which consists of neuroepithelial endfeet. Thus an affinity for neuroepithelial endfeet could partially explain their unusual intraspinal trajectory. We also show that morphology of the spinal accessory growth cones differs according to position along the accessory nerve pathway. Finally, we show that accessory motor neuron axons are in the region of their target precursors prior to the initiation of dendritic arborization. Use of DiI in fixed tissue allows study of process outgrowth in mammalian spinal cord with detail previously obtainable only in nonmammalian vertebrates.     

Postnatal development of neurons containing choline acetyltransferase in rat spinal cord: an immunocytochemical study

A monoclonal antibody to choline acetyltransferase (ChAT) has been used in an immunocytochemical study of the postnatal development of ChAT-containing neurons in cervical and thoracic spinal cord. Specimens from rat pups ranging in age from 1 to 28 days postnatal (dpn) were studied and compared with adult specimens (Barber et al., '84). The development of established cholinergic neurons, the somatic motoneurons and sympathetic preganglionic cells, has been described as has that of previously unidentified ChAT-positive neurons in the dorsal, intermediate, and central gray matter. Cell bodies of somatic and visceral motoneurons contained moderate amounts of ChAT-positive reaction product at birth that gradually increased in intensity until 14-21 dpn. The most intensely stained ChAT-positive neurons in 1-5-dpn specimens were named partition cells because this cell group extended from the central gray to an area dorsal to the lateral motoneurons, and thereby divided the spinal cord into dorsal and ventral halves. Partition cells were medium to large in size with 5-7 primary dendrites, and axons that, in fortuitous sections, could be traced into the ventrolateral motoneuron pools, the ventral funiculi, or the ventral commissure. Small ChAT-positive cells clustered around the central canal and scattered in laminae III-VI of the dorsal horn were detectable at birth. These neurons were moderately immunoreactive at 11-14 dpn and intensely ChAT positive by 21 dpn. The band of ChAT-positive terminal-like structures demonstrated in lamina III of adult specimens (Barber et al., '84) was first visible in 11-14-dpn specimens. By 28 dpn, both laminae I and III contained punctate bands that approximated the density of those observed in adult spinal cord. This investigation has demonstrated ChAT within individual neurons of developing spinal cord, and has identified a group of neurons, the partition cells, that exhibit intense ChAT-positive immunoreactivity earlier than any other putative cholinergic cells in spinal cord, including motoneurons. Another important observation has been that each ChAT-positive neuronal type achieves adult levels of staining intensity at different times during development. A likely explanation for this differential staining is that various groups of neurons acquire their mature concentration of ChAT molecules at different developmental stages. In turn, this may correlate with the maturation of cholinergic synaptic activity manifest by individual cells or groups of neurons.     

Unique developmental patterns of GABAergic neurons in rat spinal cord

Gamma-aminobutyric acid (GABA)ergic neurons have been postulated to compose an important component of local circuits in the adult spinal cord, yet their identity and axonal projections have not been well defined. We have found that, during early embryonic ages (E12-E16), both glutamic acid decarboxylase 65 (GAD65) and GABA were expressed in cell bodies and growing axons, whereas at older ages (E17-P28), they were localized primarily in terminal-like structures. To determine whether these developmental changes in GAD65 and GABA were due to an intracellular shift in the distribution pattern of GAD proteins, we used a spinal cord slice model. Initial experiments demonstrated that the pattern of GABAergic neurons within organotypic cultures mimicked the expression pattern seen in embryos. Sixteen-day-old embryonic slices grown 1 day in vitro contained many GAD65- and GAD67-labeled somata, whereas those grown 4 days in vitro contained primarily terminal-like varicosities. When isolated E14-E16 slices were grown for 4 days in vitro, the width of the GAD65-labeled ventral marginal zone decreased by 40-50%, a finding that suggests these GABAergic axons originated from sources both intrinsic and extrinsic to the slices. Finally, when axonal transport was blocked in vitro, the developmental subcellular localization of GAD65 and GAD67 was reversed, so that GABAergic cell bodies were detected at all ages examined. These data indicate that an intracellular redistribution of both forms of GAD underlie the developmental changes observed in GABAergic spinal cord neurons. Taken together, our findings suggest a rapid translocation of GAD proteins from cell bodies to synaptic terminals following axonal outgrowth and synaptogenesis.     

Nerve growth factor stimulates development of substance P in the embryonic spinal cord

Development of the putative neurotransmitter, substance P (SP), in the embryonic rat dorsal root ganglion (DRG) and spinal cord was defined in vivo. SP was not detectable by radioimmunoassay before day 17 of gestation (E17). On E17, cervical sensory ganglia contained 4 pg SP/ganglion, rising to 49 pg/ganglion at birth. The dorsal cervical spinal cord contained 0.75 ng SP/mg protein on E17, rising to 6 ng SP/mg protein on postnatal day 3. The ventral spinal cord contained approximately 20% of the SP content in the dorsal cord at each gestational age. Intrauterine forelimb amputation partially prevented the normal development increase of SP in sensory ganglia destined to innervate that limb, suggesting that target structures regulate the development of peptidergic neruons. Conversely, treatment with nerve growth factor (NGF) stimulated development of SP in the DRG. Moreover, NGF treatment increased SP in the dorsal spinal cord, suggesting that NGF can modulate development within the CNS, as well as peripheral structures. It is likely that the CNS effect reflects NGF peptidergic neruons. Conversely, treatment with nerve growth factor (NGF) stimulated development of SP in the DRG. Moreover, NGF treatment increased SP in the dorsal spinal cord, suggesting that NGF can modulate development within the CNS, as well as peripheral structures. It is likely that the CNS effect reflects NGF peptidergic neruons. Conversely, treatment with nerve growth factor (NGF) stimulated development of SP in the DRG. Moreover, NGF treatment increased SP in the dorsal spinal cord, suggesting that NGF can modulate development within the CNS, as well as peripheral structures. It is likely that the CNS effect reflects NGF action on peripheral ganglia, but a direct effect on the spinal cord has not been excluded. However, treatment with antiserum to NGF failed to significantly inhibit development of ganglion SP. The system of SP-containing neurons in the DRG may provide a convenient model for defining events regulating peptidergic maturation.     

Immunohistochemical demonstration of serotonin neurons in autonomic regions of the rat spinal cord

The immunohistochemical distribution of serotonin neurons in normal and transected spinal cords of rats was examined. Intraspinal serotonin neurons were immunostained as far rostral and caudal as T3 and Co1, respectively. All serotonin neurons were located in lamina VII and X, and most were located in spinal autonomic areas. Both bipolar and multipolar neurons were observed with many of the neurons oriented longitudinally to the long axis of the cord. Spinal neurons immunostained for serotonin were visible with and without L-tryptophan and monoamine oxidase inhibitor pretreatment.     

Target neurons for [H]corticosterone in the rat spinal cord

Rats were injected with [³H]corticosterone and their spinal cords processed for autoradiography. Nuclear concentration of the tritiated steroid was observed in motor neurons in cervical, thoracic, lumbar, and sacral regions. Nuclear concentrations of [³H]corticosterone was also observed in certain neurons of laminae VII and III in all levels of the spinal cord. Injection of unlabeled corticosterone 5 min before the [³H]corticosterone injection abolished the nuclear concentration of the adrenal steroid. These results provide the morphological basis for a direct genomic action of corticosterone in spinal motor neurons and in neurons of laminae III and VII.     

Cervical prephrenic interneurons in the normal and lesioned spinal cord of the adult rat

Although monosynaptic bulbospinal projections to phrenic motoneurons have been extensively described, little is known about the organization of phrenic premotor neurons in the adult rat spinal cord. Because interneurons may play an important role in normal breathing and recovery following spinal cord injury, the present study has used anterograde and transneuronal retrograde tracing to study their distribution and synaptic relations. Exclusive unilateral, first-order labeling of the phrenic motoneuron pool with pseudorabies virus demonstrated a substantial number of second-order, bilaterally distributed cervical interneurons predominantly in the dorsal horn and around the central canal. Combined transneuronal and anterograde tracing revealed ventral respiratory column projections to prephrenic interneurons, suggesting that some propriospinal relays exist between medullary neurons and the phrenic nucleus. Dual-labeling studies with pseudorabies virus recombinants also showed prephrenic interneurons integrated with either contralateral phrenic or intercostal motoneuron pools. The stability of interneuronal pseudorabies virus labeling patterns following lateral cervical hemisection was then addressed. Except for fewer infected contralateral interneurons at the level of the central canal, the number and distribution of phrenic-associated interneurons was not significantly altered 2 weeks posthemisection (i.e., the point at which the earliest postinjury recovery of phrenic activity has been reported). These results demonstrate a heterogeneous population of phrenic-related interneurons. Their connectivity and relative stability after cervical hemisection raise speculation for potentially diverse roles in modulating phrenic function normally and postinjury.     

Reelin inhibits migration of sympathetic preganglionic neurons in the spinal cord of the chick

The present study examined the effects of Reelin in the migration of sympathetic preganglionic neurons (SPN) in the spinal cord of the chick. SPN in the chick first migrate from the neuroepithelium to the ventrolateral spinal cord. They then undergo a secondary migration to cluster adjacent to the central canal, forming the column of Terni (CT). During secondary migration, abundant Reelin is found in large areas of the ventral spinal cord; the only areas devoid of Reelin are areas occupied by SPN or somatic motor neurons and the pathway along which SPN migrate. Ectopic expression of Reelin in the pathway of SPN through electroporation of full-length Reelin DNA stopped SPN migration toward their destination. The spatiotemporal pattern of Reelin expression, along with the inhibition of SPN migration by exogenous Reelin, suggests that Reelin functions as a barrier to SPN migration during normal development of the spinal cord.