The central projections of specific subpopulations of lumbar primary afferents were selectively labeled with the lipophilic tracer DiI in fixed preparations of the chicken embryo. Muscle or cutaneous afferents were selectively labeled by applying DiI to identified peripheral nerves. Medial or lateral afferent populations were selectively labeled by partially lesioning the dorsal root. Muscle and cutaneous afferent populations each contribute to both the medial and the lateral afferent populations. Medial muscle afferents terminate in the intermediate zone and lateral motor column proximally, but only in the intermediate zone distally. Lateral muscle afferents terminate in a ventrolateral region of the dorsal horn both proximally and distally. Medial cutaneous afferents terminate predominantly in lamina III, but a few terminate in the medial region of the intermediate zone. Lateral cutaneous afferents terminate in lamina II and in a ventrolateral region of the dorsal horn. On the basis of the principle termination patterns, specific termination fields were defined and related to the classical cytoarchitectonics of the spinal gray matter. Differential retrograde tracing from the spinal cord with fluorescent dextran-amines demonstrated that the medial afferents originate from the earlier-generated ventrolateral population of large sensory cell bodies, while the lateral afferents originate from the later-generated dorsomedial population of small sensory cell bodies. The medial afferents establish their central projections earlier than the lateral afferents, but for each subpopulation the initial pattern of termination prefigures the mature pattern, throughout the segmental range of the collaterals. Birthdating with 3H-thymidine showed that potential target neurons in the different terminal fields within the dorsal horn are born at different times. In particular, interneurons in lamina II are born after those in lamina III, paralleling the early and late termination of cutaneous afferents in these laminae. Our observations support the notion that primary afferents recognize specific cues in the spinal cord, but also implicate the relative timing of afferent and target differentiation as an important determinant of primary afferent termination patterns.
The literature on the anatomical organization of primary sensory afferents, though extensive, contains relatively little information about the longitudinal extent of the central collateral projections. Our understanding of intersegmental sensorimotor integration in the spinal cord and of the developmental mechanisms that establish its underlying circuitry could be significantly enhanced by a more complete description of these projections. To address this issue from a developmental perspective, we labeled the central projections of lumbar primary afferents in fixed preparations of the chicken embryo with the lipophilic tracer DiI. At late embryonic stages, the afferent projections had the following characteristics: Primary afferents originating from a single lumbar dorsal root ganglion bifurcated to project longitudinally in the dorsal funiculus or Lissauer's tract. Dorsal funiculus axons extended up to seven segments caudally and to at least ten segments rostrally, whereas axons in Lissauer's tract extended up to seven segments in each direction. Collaterals branched off the longitudinal axons over a range of about seven segments in each direction. Within this range, collaterals to specific terminal fields exhibited more restricted ranges. The development of these longitudinal patterns during earlier embryonic stages was followed from the time the afferents first reached the neural tube on day 4 of embryogenesis. The longitudinal axons lengthened as a single bundle up to day 10, with medial axons consistently longer than lateral axons. After day 10, the longitudinal axons were segregated into the dorsal funiculus and Lissauer's tract. Collaterals sprouted after about 2 days of longitudinal axon growth, by which time the axons had extended several segments in each direction. The segmental range over which collaterals were present reached a maximum of 20 segments at day 10. Collaterals to the different terminal areas differed in their segmental ranges already by this time. After day 10, the total segmental range of collaterals decreased to the stable level of about seven segments in each direction, which is characteristic of late-stage embryos.
The axonal projections of the Hofmann nuclei in the spinal cord of the late stage chicken embryo
The projection pattern of the neurons of the paragriseal Hofmann nuclei was mapped in the chicken embryo using the lipophilic tracer DiI. This report focuses on the pattern of projection from the Hofmann nuclei major observed 1-4 days prior to hatching, at which time the projection appears to be substantially developed. (1) Each neuron extends a commissural axon through the ventral gray matter and across the midline in the ventral commissure. The axons originating from a single Hofmann nucleus cross within a stretch of the cord equivalent to about one spinal segment. There is a small overlap of the axon populations originating from adjacent Hofmann nuclei. After reaching the contralateral ventral columns the individual axons bifurcate and extend rostrally and caudally up to 5 spinal segments in each direction. The rostral and caudal trajectories differ; the rostral axons shift progressively more laterally while the caudal axons tend not to deviate from their initial course. (2) Throughout their longitudinal course the axons give rise to terminal collaterals that are concentrated in lamina 8. Rostrally and caudally the terminals decrease in density and become increasingly scattered. (3) Hofmann neurons are multipolar with 4-5 laterally directed primary dendrites whose arbors are restricted to the Hofmann nucleus major within which the neurons reside. (4) Hofmann neurons receive afferent terminals from a longitudinal column of commissural interneurons located contralaterally in close approximation to the central canal. Each Hofmann nucleus major is innervated by a rostrocaudally restricted subset of these presynaptic neurons. The axon trajectories of the presynaptic neurons are similar to those of the Hofmann neurons. (5) Paragriseal neurons that are not located within Hofmann nuclei major are also commissural intersegmental interneurons and tend to be clustered segmentally. The segmentation is clearest for the Hofmann nuclei minor, which are clusters of neurons iterated along the ventrolateral margin of the thoracic spinal cord but not organized in protruding lobes.
Development of an Identified Spinal Commissural Interneuron Population in an Amniote: Neurons of the Avian Hofmann Nuclei
The commissural interneurons of the Hofmann nuclei (HN) of the avian spinal cord (The axonal projections of the Hofmann nuclei in the spinal cord of the late stage chicken embryo, Anat Embryol (Berl), A.L. Eide, 1996, Vol 193, pp 543-557) provide a unique opportunity to describe the development of an identified spinal commissural axon projection and its terminal collaterals in an amniote vertebrate. Here, we use the lipophilic tracer Dil to label these and other commissural projections anterogradely and retrogradely from the time the HN neurons are born. [3H]thymidine birthdating shows that the final mitoses of HN neurons occur at stages 21-24 [developmental day (d) 4]. By direct comparison, this follows the generation of motoneurons and of large, dorsally located commissural interneurons. The first HN neurons reach the ventrolateral margin of the spinal cord by d6 by a radial migration through the ventral horn. Radial migration occurs after the extension of HN axons across the midline. Thus, HN neurons are determined to be commissural interneurons before attaining their definitive locations. The HN neurons subsequently aggregate into segmentally iterated clusters at the ventrolateral margin of the spinal cord by d8. Also by d8 their logitudinal axons attain mature extent in the ventral funiculus of the contralateral side and begin to sprout collaterals. The collaterals are directed predominantly toward the medial aspect of the ventral horn at all stages, forming by d12 a dense thicket of terminals that thins out over several segments to each side of the HN of origin. The initial direction of collateral outgrowth is largely appropriate for the mature termination pattern of the HN. Terminal arbors, however, are less focused at early developmental stages than at later stages.
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