Segmental Specificity of Chick Sympathetic Preganglionic Projections Is Influenced by Preganglionic Neurons from Neighboring Spinal Cord Segments

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The Journal of Neuroscience, December 15, 1998, 18(24):10473-10480

Segmental Specificity of Chick Sympathetic Preganglionic Projections Is Influenced by Preganglionic Neurons from Neighboring Spinal Cord Segments
Joseph W. Yip, Yee Ping L. Yip, and Christine Capriotti
Department of Neurobiology, School of Medicine, University of Pittsburgh, Pittsburgh, Pennsylvania 15261

  ABSTRACT

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Sympathetic preganglionic neurons of the chick are located between the brachial and lumbosacral enlargements of the spinalcord. Their axons exit the spinal cord via their adjacent ventralroots and project rostrally or caudally along the sympathetictrunk to innervate sympathetic ganglia. The projections of sympatheticpreganglionic neurons are segmentally specific. Neurons from the16th cervical (C16) and the first thoracic (T1) spinal cord segmentsproject predominantly in the rostral direction, whereas thosefrom the fifth thoracic (T5) to the first lumbar (L1) spinal segmentsproject predominantly in the caudal direction. Neurons from interveningspinal cord segments (T2-T4) project in rostral and caudal directions.In the present study, neural tube manipulations show that thedirection of preganglionic projections is altered by both theelimination and addition of preganglionic neurons projecting intothe sympathetic trunk from neighboring segments. The present studyalso compares the projections of preganglionic neurons from transplantsof multiple neural tube segments with those from transplants ofsingle neural tube segments reported in a previous study (Yip,1987). In the previous study when single thoracic neural tubesegments were transplanted to the cervical level, preganglionicneurons did not maintain their original projection patterns. Thepresent study found that, when contiguous neighboring segmentswere transplanted to the cervical level, preganglionic neuronsmaintained projection patterns characteristic of their originalsegmental levels. These results indicate that the direction ofpreganglionic projections can be influenced by neurons from neighboringsegments, suggesting that the formation of segmentally specificpreganglionic projections during embryogenesis may involve theinteractions of preganglionic neurons with those from neighboringspinal cordsegments.

Key words: axon guidance; competition; transplantation; autonomic neurons; chick embryo; neuronal interactions

  INTRODUCTION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Projections of sympathetic preganglionic neurons in the sympathetic trunk of birds and mammals are segmentally specific (Langley1892, 1904; Lichtman et al., 1980; Rubin and Purves, 1980; Yip,1990; Forehand et al., 1994; Yip et al., 1998). In the chick,for example, preganglionic neurons arising from the first thoracicspinal cord segment (T1) project predominantly in the rostraldirection, whereas those arising from the last thoracic spinalcord segment (T7) project predominantly in the caudal direction.The mechanisms underlying the establishment of these segmentallyspecific projection patterns are not fully understood. Our recentstudy shows that the projections of these neurons are not determinedintrinsically by the segmental origins of their cell bodies inthe spinal cord (Yip et al., 1998). A previous study has shownthat the segmentally specific projections of preganglionic neuronsdo not require their target neurons $---$ sympathetic ganglion cells(Yip, 1987). Because neither the intrinsic properties of preganglionicneurons nor their target cells appear to be responsible for thesegmentally specific projections, it is likely that some factoror factors along the projection pathway in the sympathetic trunkmay play a role in the development of preganglionic projectionpatterns.

In addition to sympathetic ganglion cells, the sympathetic trunk also contains axons of preganglionic neurons and Schwanncells. Schwann cells, however, do not seem to be required forthe formation of segmentally specific preganglionic projectionsbecause preganglionic projections are not affected by neural crestremoval (Yip, 1987). Because each ganglion is innervated by preganglionicneurons arising from several spinal cord segments (Langley, 1904;Njå and Purves, 1977; Yip, 1986; Forehand, 1994), axons of preganglionicneurons from multiple spinal cord segments share the same pathwayto arrive at their target ganglia. In the development of the nervoussystem it has been shown that axonal projections can be influencedby other axons. For example, axons may be guided by pioneer fibers(Bentley and Keshishian, 1982). Axon guidance, moreover, may bemediated by fasciculation with existing fibers (Raper et al.,1983) as well as by repulsive interactions with other fibers (Kapfhammerand Raper, 1987). Are the segmentally specific preganglionic projectionsinfluenced by axons from neighboring spinalsegments?

A previous study has shown that, when single segments of spinal cord containing preganglionic neurons are transplanted toa cervical level that contains no preganglionic neurons, the transplantedpreganglionic neurons do not maintain their original projectionpatterns (Yip, 1990). The altered projection patterns of preganglionicneurons that have been transplanted to locations that have nopreganglionic neighbors suggest that preganglionic projectionsmay be influenced by interactions with neighboring preganglionicneurons. In the present study we test this possibility by addingor eliminating preganglionic neurons in neighboring segments ofnormal thoracic spinal cord. Additionally, contiguous neighboringsegments containing preganglionic neurons are transplanted tothe cervical level. Results from these studies suggest that thesegmental specificity of sympathetic preganglionic projectionsis influenced by preganglionic neurons from neighboring spinalcordsegments.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

White leghorn eggs (Keystone Mills, Ephrata, PA) were used in the present study. All embryos were incubated at 37°C and 70%humidity in a forced-draft incubator and staged according to Hamburgerand Hamilton (1951). Embryo manipulations were performed at stage14. For embryo manipulation, a window was opened in the shellof the egg. Segmental levels were determined by counting somites(Levi-Montalcini, 1950). Carbon particles were used to mark therostrocaudal boundaries of the neural tube segments of interest.Neural tube segments then were removed from embryos with a tungstenneedle and transplanted to different spinal levels. After surgicalmanipulation the windows were sealed with cellophane tape, andthe embryos were returned to the incubator until death at stage30/31. For each type of surgical manipulation performed, an additionalset of sham-operated embryos was used. In these control embryosthe neural tube segments were removed and reinserted into thesame embryo. Projection patterns in all sham-operated embryoswere determined to be the same as in normalembryos.

To determine segmental levels of the spinal cord at the time of death, we took the T1 segmental level to be the spinal leveljust caudal to the brachial plexus. The boundaries of each segmentwere taken to be halfway between the midpoints of adjacent dorsalroot ganglia. Only those embryos that showed manipulations atthe appropriate levels were used for dataanalysis.

Specificity of sympathetic preganglionic projections from each spinal cord level
The sympathetic chain ganglia, which are arranged segmentally from cervical throughout the sacral levels, lie along each sideof the vertebral column. Ganglion cells are innervated by preganglionicneurons that are located between the brachial and lumbosacralenlargements of the spinal cord. Preganglionic neurons exit thespinal cord via their adjacent ventral roots and enter into thesympathetic trunk where they project rostrally or caudally toinnervate the chain of ganglia (Yip, 1990). To visualize the preganglioniccell column, we sectioned stage 30 embryos at 20 µm in the horizontalplane with a cryostat and immunostained with E/C8, a monoclonalantibody against neurofilaments (a generous gift of Dr. G. Ciment,Oregon Health Sciences University, Portland, OR). Detailed immunostainingprocedures have been described in a previous publication (Yipet al., 1995). The mature pattern of preganglionic projectionsfrom each spinal cord segment was examined in stage 30/31 embryosby anterograde labeling with horseradish peroxidase (HRP) or DiI.The details of axonal tracing techniques are describedbelow.

Removal of neighboring neural tube segments
The T2-T4 neural tube segments were removed unilaterally or bilaterally and replaced with a similar length of cervical neuraltube (C11-C13) that does not give rise to sympathetic preganglionicneurons (see Fig. 2A). This eliminated the caudal neighbors ofthe T1 segment and the rostral neighbors of the T5 segment. Thecontralateral side served as a control. Only those embryos thatat the time of death clearly showed boundaries of surgery at theT2 and T4 levels were used. To ensure that this surgical manipulationeliminated preganglionic neurons from the T2-T4 spinal levels,we sectioned one set of operated embryos at 20 µm in the transverseor horizontal plane with a cryostat and immunostained with E/C8as described in a previous publication (Yip et al., 1995). Inanother set of embryos, preganglionic projections from the T1or T5 spinal cord segments were evaluated by using anterogradelabeling with HRP or DiI on both the control and experimentalsides of the embryo. Finally, because the T3 ganglion normallyreceives innervation from preganglionic neurons at the T2-T4 spinallevels, retrograde labeling with DiI was used to evaluate changesin preganglionic axonal projections to the T3 ganglia in anotherset of embryos. To quantify the number of T1 and T5 preganglionicneurons projecting to the T3 ganglia, we used retrograde labelingwith fluorescent dextran amine dyes. Details of HRP, DiI, anddextran amine labeling are describedbelow.

Addition of neighboring neural tube segments
To increase preganglionic projections from neighboring segments rostral to the T1 segment, we removed the cervical neuraltube from the C13-C16 spinal levels of a host embryo bilaterallyand replaced it with a thoracic neural tube from the approximateT1-T4 spinal levels of a similarly staged donor embryo (see Fig.5A). Both experimental and donor embryos were returned to theincubator until death. Donor embryos were examined to assure thatthe transplanted neural tube segments were from the thoracic level.Only those host embryos that received thoracic spinal cord wereanalyzed. Anterograde labeling with HRP and DiI was used to determinethe projection pattern of preganglionic neurons from the T1 spinalcord segment of the hostembryos.

Transplantation of multiple neural tube segments to a novel environment
The cervical level of the spinal cord normally does not contain preganglionic neurons. When several contiguous thoracic spinalcord segments were transplanted into the cervical level, the transplantedneurons were situated in a novel environment. For these transplantationsthe C9-C12 neural tube segments were removed bilaterally fromhost embryos and replaced with the T1-T4 neural tube segmentsfrom similarly staged donor embryos. Anterograde labeling withHRP was used to assess preganglionic axonal projections from thetransplanted T1 and T4segments.

Axonal tracing with HRP and DiI
For neuronal labeling the embryos were eviscerated in Tyrode solution, and a dorsal laminectomy was performed to expose thespinal cord. For all anterograde studies the sections were cutin the sagittal plane; for retrograde studies the sections werecut in the horizontalplane.
HRP labeling. For anterograde labeling of preganglionic axons with HRP, ~0.2 µl of 30% HRP/1% lysolecithin solution was pressure-injectedwith a micropipette (20 µm tip diameter) into the appropriatespinal cord segment(s). For retrograde labeling of preganglionicneurons, a similar volume of HRP was injected into the T3 ganglia.Injected embryos were maintained in oxygenated Tyrode solutionat 31°C for 5-7 hr to allow for transport of HRP (Landmesser,1978); thereafter, they were fixed for 1 hr with a phosphate-bufferedfixative consisting of a mixture of 1% paraformaldehyde, 2.5%glutaraldehyde, and 4% sucrose; they were equilibrated in 30%phosphate-buffered sucrose; and they were sectioned serially witha cryostat at 30 µm. All sections were mounted on Superfrost Plusslides (Fisher Scientific, Pittsburgh, PA) and reacted for thepresence of HRP, using diaminobenzidine as the chromogen (Adams,1981).
DiI labeling. Embryos were placed in a fixative consisting of 4% paraformaldehyde in 0.1 M phosphate buffer. For anterogradelabeling of preganglionic axons, DiI crystals (Molecular Probes,Eugene, OR) mixed in silicone grease (Lubriseal, Thomas Scientific,Swedesboro, NJ) (Mirnics and Koerber, 1995) were embedded in thecentral canal of the appropriate spinal cord segment(s) (Yip etal., 1998). All neural tube segments that were not embedded withDiI were removed to eliminate diffusion of the dye. For retrogradelabeling of preganglionic neurons, DiI (0.25% in 100% alcohol;Honig and Hume, 1986) was pressure-injected into the T3 ganglia.All DiI-treated embryos were incubated at 37°C for 3-4 d, embeddedin 7% agar, and sectioned at 150 µm with avibratome.

Fluorescent dextran amine labeling for cell counts
Because individual preganglionic neurons in the spinal cord are difficult to distinguish with retrograde DiI labeling, retrogradelabeling with fluorescent dextran amines was used to evaluatechanges in the percentages of preganglionic neurons at the T1or T5 spinal cord segment that project to the T3 ganglia. Preganglionicneurons projecting to the T3 ganglia were retrogradely labeledby injecting ~0.2 µl of 25% rhodamine-conjugated dextran aminein 1% Triton X-100 into the T3 ganglia. The preparation was incubatedfor 5-6 hr at 31°C in oxygenated Tyrode solution to allow forretrograde transport of the dye. To delineate the boundaries ofthe T1 and T5 spinal cord segments, we then cut the ventral rootson either side of the T1 and T5 segments. The preparation wasreincubated for an additional 1/2 hr to allow the cut nerves toseal. Then ~0.2 µl of 25% FITC-conjugated dextran amine in 1%Triton X-100 was injected into the T1 and the T5 ganglia; thiseffectively labeled all preganglionic neurons in those segments.The preparation was reincubated again for an additional 5-6 hr.Embryos then were fixed in 4% paraformaldehyde in 0.1 M phosphatebuffer overnight at 4°C, equilibrated in 30% phosphate-bufferedsucrose, and serially sectioned with a cryostat at 20 µm in thetransverse plane. The percentage of T1 and T5 preganglionic neuronsprojecting to the T3 ganglia was calculated by dividing the numberof rhodamine-labeled cells in the T1 and T5 segments by the sumof fluorescein-labeled cells and rhodamine-labeled cells in thosesegments.

  RESULTS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Preganglionic projections from each spinal cord segment are specific

The preganglionic cell column of the chick (column of Terni) was identified in the thoracic spinal cord by Terni (1924) andalso by Levi-Montalcini (1950), using silver staining. In thepresent study, immunostaining with monoclonal antibody E/C8 wasused to visualize the column of Terni in stage 30 embryos (n =5). The column of Terni extends from the C16-L1 spinal levels(Fig. 1A). The width of the column appears uniform throughoutthe thoracic levels but tapers off toward the rostral (C16) andcaudal (L1) ends. The projections of preganglionic neurons fromindividual spinal cord segments were anterogradely labeled witheither DiI or HRP in stage 30 embryos. Only one spinal cord segmentwas labeled in each embryo. As shown in Figure 1B, the projectionpattern of these neurons is segmentally specific. Projectionsfrom rostral spinal cord segments (C16 and T1) are predominantlyrostral in the sympathetic trunk, whereas projections from caudalspinal cord segments (T5-L1) are predominantly caudal. Interveningspinal cord segments (T2-T4) show rostral as well as caudal projections.

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Figure 1. A, Location of the preganglionic cell column in the spinal cord. The micrograph shows a horizontal section from a stage 30 embryo that has been immunostained with monoclonal antibody E/C8. Preganglionic neurons (arrows) cluster around the central canal of the spinal cord and extend from the C16 to the L1 spinal cord segments. B, Specificity of sympathetic preganglionic projections from each spinal cord segment. Micrographs show sagittal sections through the sympathetic trunk of stage 30 embryos. Anterograde labeling with DiI shows that, within the sympathetic trunk, preganglionic neurons from rostral segments (C16 and T1) project predominantly in the rostral direction, whereas preganglionic neurons from caudal segments (T5-L1) project predominantly in the caudal direction (rostral is up; dorsal is to the right). Intervening spinal cord segments (T2-T4) show rostral as well as caudal projections. Note that DiI injected into the spinal cord anterogradely labels sympathetic preganglionic axons and also retrogradely labels dorsal root ganglia. In this plane of section, only labeled sympathetic preganglionic axons and dorsal root ganglia (D) are visible. The spinal cord, where DiI was injected, is medial to this plane of section and is not visible. A similar plane of section showing retrogradely labeled dorsal ganglia is found also in Figures 4 and 5. Scale bar, 1 mm.

Specificity of preganglionic projections is altered with removal of neighboring neural tube segments

To test whether preganglionic neurons from neighboring spinal cord segments can affect the segmental specificity of preganglionicprojections, we examined the T1 and T5 preganglionic projectionsin embryos that had the T2-T4 spinal cord segments on one sidereplaced with the C11-C13 spinal cord segments. Because cervicalspinal cord does not contain preganglionic neurons, this effectivelyeliminates preganglionic neurons in the T2-T4 spinal levels (Fig.2A). In one set of operated embryos (n = 6) immunostaining wasused to show that preganglionic neurons were indeed absent betweenthe T2 and T4 spinal levels on the experimental side (Fig. 2B,C).

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Figure 2. Removal of neighboring neural tube segments. A, The T2-T4 neural tube segments were removed unilaterally from a stage 14 embryo and replaced with the C11-C13 neural tube segments. The contralateral side served as a control. B, Transverse section from an operated stage 30 embryo. Immunostaining with E/C8 shows the absence of preganglionic neurons on the operated (right) side of the embryo. The arrow shows preganglionic neurons on the control (left) side of the embryo. C, Horizontal section from an operated stage 30 embryo. Immunostaining with E/C8 shows a discontinuous preganglionic cell column on the operated (right) side of the embryo. Scale bars: B, 250 µm; C, 500 µm.

The pattern of preganglionic projections was determined by using retrograde labeling with DiI and dextran amines and anterogradelabeling with DiI. Retrograde labeling with DiI injected intothe T3 ganglia revealed that the T3 ganglion on the control sideis supplied mostly by preganglionic axons from the T2-T4 spinalcord segments, with very little contribution from the T1 and T5spinal cord segments. The T3 ganglion on the operated side, incontrast, is supplied almost exclusively by preganglionic neuronsfrom the T1 and T5 spinal cord segments (n = 24) (Fig. 3). Thus,in the absence of preganglionic neurons from the T2 to T4 spinalcord segments, more T1 preganglionic neurons now project caudallyand more T5 preganglionic neurons project rostrally to the T3ganglion. Differences in the number of T1 or T5 preganglionicneurons projecting to the T3 ganglion on the experimental andthe control sides of operated embryos were quantified furtherby using retrograde fluorescent dextran amine labeling (n = 8;data not shown). Results show that 19 ± 3.1% (mean ± SD) of thetotal number of T1 preganglionic neurons on the experimental sidesent axons to the T3 ganglion, whereas only 3 ± 1.2% of the T1preganglionic neurons on the control side sent axons to the T3ganglion. Additionally, an average of 36 ± 4.2% of the T5 preganglionicneurons on the experimental side sent their axons to the T3 ganglion,whereas only 3 ± 1.5% of the T5 preganglionic neurons on the controlside sent their axons to the T3 ganglion.

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Figure 3. T2-T4 neural tube removal changes the distribution of preganglionic neurons projecting to the T3 ganglia. A, Distribution of preganglionic neurons projecting to the T3 ganglia of operated stage 30/31 embryos as determined by retrograde labeling with DiI (n = 24). Each set of bars represents one embryo. Shaded bars represent the control side, and filled bars represent the experimental side of the embryo. On the control side the majority of preganglionic neurons projecting to the T3 ganglia is from the T2-T4 spinal segments, with few preganglionic neurons projecting from the T1 or T5 segments; those T1 and T5 neurons that did project to T3 ganglia were found close to the T2 and T4 borders, respectively. On the experimental side, T2-T4 neural tube removal resulted in the absence of preganglionic neurons from those segments; only preganglionic neurons from the T1 and T5 spinal cord segments projected to the T3 ganglia, and these neurons were found throughout the entire T1 and T5 segments. B, Micrograph of a horizontal section from one of the experimental embryos. Note the extensive labeling at the T1 and T5 spinal levels on the experimental (right) side of the embryo (filled arrows). Labeling on the control (left) side of the embryo was confined, for the most part, to the T2-T4 spinal levels (open arrows). Scale bar, 500 µm.

Anterograde labeling studies also were done subsequent to the removal of the T2-T4 spinal segments. In the absence of theirrostral neighbors, T5 preganglionic neurons on the experimentalside projected 31/2 to six segments rostrally, compared with only1/2 to 11/2 segments rostrally on the control side. Caudal projectionswere similar on both control and experimental sides (Fig. 4B,C).Although less striking, results from anterograde labeling of T1preganglionic neurons also showed a change in projection patterns(Fig. 4A). In 8 of 11 cases, T1 preganglionic neurons respondedto the absence of caudal neighbors and projected 11/2 to two segmentscaudally, compared with their normal caudal projections of notmore than one segment (data not shown). Rostral projections fromthe T1 segment of experimental embryos were similar to those ofnormal embryos. Together, these results show that the segmentalspecificity of preganglionic projections can be altered with theremoval of neighboring spinal cord segments.

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Figure 4. Specificity of preganglionic projections is altered with removal of the neighboring neural tube segments. A, Anterograde DiI labeling of T1 preganglionic neurons in a stage 30 neural-tube-removed embryo shows more caudal projections on the experimental side (left) than on the control side (right). B, Anterograde DiI labeling of T5 preganglionic neurons in a stage 30 neural-tube-removed embryo shows both rostral and caudal projections on the experimental side (left), compared with mostly caudal projections on the control side (right). C, T5 preganglionic projections in neural-tube-removed stage 30/31 embryos as determined by anterograde labeling with DiI (n = 17). Each set of bars represents one embryo. The filled bars show projections on the control side, and the open bars show projections on the experimental side. Taking T5 as the origin, rostral projections (R) are to the left, and caudal projections (C) are to the right. T5 projections on the control side were predominantly caudal, extending four to six segments caudally and not more than 1.5 segments rostrally. Projections on the experimental side, however, were bidirectional, extending three to six segments rostrally and four to six segments caudally. Scale bar, 500 µm.

Specificity of preganglionic projections is altered with the addition of preganglionic neurons in neighboring neural tube segments

In normal embryos, preganglionic neurons that are located at the rostral boundary of the preganglionic cell column (C16-T1)have few or no rostral neighbors and tend to project predominantlyin the rostral direction. To explore the possibility that thedirectional projections of preganglionic neurons at the rostralboundary of the cell column are influenced by the fact that theyconfront fewer axons from neighboring segments, we extended thenormal preganglionic cell column to the cervical level by replacingcervical spinal cord segments in host embryos with thoracic neuraltube from donor embryos (Fig. 5A). In the operated embryos, axonsfrom T1 preganglionic neurons encountered more axons from thetransplanted segments. Preganglionic projections from both sidesof the native T1 spinal cord segment were evaluated to determinethe effects of additional neighbor axons. In all cases (n = 20),preganglionic neurons from the native T1 spinal cord segment didnot retain their predominantly rostral projections but projectedinstead in both directions (Fig. 5B). On average, they projectedtwo to three segments caudally instead of the not more than onesegment found in normal embryos (Yip, 1990). However, rostralprojections from native T1 preganglionic neurons appeared normal.The increased caudal projections from T1 preganglionic neuronsin these experimental embryos show that the specificity of preganglionicprojections also can be altered with the addition of preganglionicneurons in neighboring spinal cord segments.

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Figure 5. The addition of preganglionic neurons in neighboring neural tube segments alters the projections of preganglionic neurons. A, The T1-T4 neural tube segments were removed from a stage 14 donor embryo and transplanted to the C13-C16 spinal level of a similarly staged host. This operation results in transplanted T1-T4 spinal segments immediately rostral to the native T1-T4 spinal segments of the host embryo. B, Anterograde DiI labeling of native T1 preganglionic neurons in a stage 30 experimental embryo shows projections in both rostral and caudal directions. Note that T1 preganglionic projections in the normal embryo (see Fig. 1B) are predominantly rostral. Scale bar, 500 µm.

Specificity of preganglionic projections is retained with the transplantation of multiple neural tube segments to a novel environment

A previous study showed that, when a single neural tube segment (T1 or T4) was transplanted to the cervical level, the transplantedpreganglionic neurons projected more or less equally in both directions(Fig. 6C,D) instead of in their normal predominantly rostral orcaudal direction (Yip, 1990). The change in directional projectionof these neurons may be attributable to the lack of interactionwith neurons from neighboring spinal cord segments. To investigatethis possibility, we transplanted contiguous T1-T4 spinal cordsegments to the C9-C12 level. Results showed that, when the T1-T4spinal cord segments were transplanted as a whole (n = 10), thetransplanted T1 neurons projected predominantly in the rostraldirection (Fig. 6A), and the transplanted T4 neurons projectedpredominantly in the caudal direction (Fig. 6B). This result furthershows that the specificity of preganglionic projections can beinfluenced by neurons from neighboring spinal cord segments.

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Figure 6. Transplantation of neural tube segments to a novel environment. Anterograde labeling with HRP was used to determine projection patterns. When contiguous T1-T4 neural tube segments were transplanted to the cervical level (C9-C12), the transplanted T1 preganglionic neurons projected predominantly in the rostral direction (A), and T4 preganglionic neurons projected predominantly in the caudal direction (B). These results differ from those of a previous study showing that, when single T1 neural tube segments were transplanted to the C9 level without their neighboring segments, the transplanted T1 preganglionic neurons projected more or less equally in both rostral and caudal directions (C). Similarly, when single T4 neural tube segments were transplanted to the C9 level, T4 preganglionic neurons also projected more or less equally in both directions (D). C and D are reprinted from Yip (1990). Scale bar, 400 µm.

  DISCUSSION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

The establishment of the segmentally specific projection patterns of preganglionic neurons is likely to involve many factors.It has been shown that these patterns are not determined by thesegmental origins of preganglionic neurons (Yip et al., 1998).It also has been shown that specific projections of preganglionicneurons do not require target sympathetic ganglia (Yip, 1987).In the present study the elimination and addition of preganglionicaxons from the sympathetic trunk, as well as the transplantationof neighboring segments to a novel environment, all show thatpreganglionic axons from neighboring segments can influence projectionpatterns. Changes in the preganglionic projection patterns reportedhere were observed in stage 30/31 embryos, which is before theperiod of preganglionic cell death (stages 34-36; Oppenheim etal., 1982). These results, therefore, suggest that changes inpreganglionic projection patterns are likely the result of theredistribution in the number of rostrally or caudally projectingneurons rather than the selective survival of neurons that haveprojected into the denervatedterritories.

That the pattern of axonal projections can be influenced by neurons from a neighboring segment also has been observed in theleech (Gao and Macagno, 1987a,b). During development, severalidentified neurons (HA, AP, and AE neurons) have processes thatinitially overlap with their homologs in adjacent ganglia. Normally,the processes from the homologs eventually retract. However, ifthese neurons are ablated, their homologs in adjacent gangliaretain their extraneous processes and take over the territoriesof the ablated neurons. These results suggest that the patternof axonal projections in the leech may result from the competitiveinteractions among homologous neurons. Indeed, a more recent studyin another identified leech neuron (P_o neuron) suggests that theextent and direction of its axonal growth depend on the inhibitoryinteractions between the segmental homologs (Gan and Macagno,1995). In the avian sensory system the competitive interactionsamong axons from neighboring dorsal root ganglia (DRG) also havebeen implicated in the development of sensory projection and innervationpatterns in the chick hind limb (Scott, 1984). When selected DRGwere deleted through neural crest removal, the distribution ofaxonal projections from neighboring intact DRG were shifted towardthe deleted pathways, and the dermatomes of the intact DRG wereenlarged. The establishment of specific neuronal patterns in thesesystems, therefore, appears to involve the competitive interactionsof neurons with each other. However, this is not the case in thesomatic motor system. After partial deletion of the spinal cord,the projection pattern of the somatic motor neurons in the remainingsegments was unaltered, and muscles for which the innervationsource was removed by spinal cord deletion remained uninnervated(Lance-Jones and Landmesser, 1980).

The reason that somatic motor and autonomic neurons differ in their response to partial deletion of the spinal cord is notclear but may be attributed to functional differences betweenthe somatic motor and the autonomic systems. In the somatic motorsystem the neurons must be able to innervate their respectivetarget muscles selectively for the control of fine motor movements.Such degree of specificity may not be necessary for autonomicneurons. Sympathetic neurons innervate smooth muscles of bloodvessels and skin that are distributed throughout the body. Becausepreganglionic neurons in different spinal cord segments will elicitautonomic responses such as vasoconstriction and piloerectionat different rostrocaudal levels, neurons of the same class mustspan multiple segments, if not the entire preganglionic cell column.Neuronal interactions among preganglionic neurons from neighboringsegments during outgrowth would ensure that all target cells becomeinnervated.

The present study does not address how preganglionic neurons from neighboring segments might interact to produce segmentallyspecific projections. However, in a preliminary study that usedHRP to label a small number of neurons, preganglionic axons havebeen observed to make hairpin turns near the point at which axonsenter the sympathetic trunk (Yip et al., 1996), suggesting thataxons can make rostrocaudal choices depending on what they encounteralong their pathway. Axons from neighboring segments may influencethese choices directly through axon-axon interactions or indirectlythrough substrate modification or competition for space or trophicfactors. Anterograde labeling with lipophilic dyes has shown thatduring normal development preganglionic axons from neighboringspinal cord segments do appose one another during outgrowth inthe sympathetic trunk (Yip et al., 1996); thus the effects ofaxon-axon interactions cannot be ruled out. It is also possiblethat preganglionic axons compete for trophic factors along theirpathway. A previous study showed that the cells in the local environmentof the preganglionic pathway are derived from the somite. Moreover,in the absence of the somitic mesoderm, many preganglionic axonsfail to project to their target region (Yip, 1996). This findingsuggests that the projection of preganglionic neurons dependson some factors in the somitic mesoderm. Limited supplies of suchfactors could result in competition among preganglionic neurons.Results from the present study are consistent with the hypothesisthat preganglionic neurons compete for some factor(s) along theirpathway. For example, when the T2-T4 spinal cord segments wereremoved, decreased competition in the pathway caudal to T1 androstral to T5 might explain the caudal projection of some T1 neuronsand the rostral projection of T5 neurons. Conversely, when additionalaxons were introduced in the pathway rostral to the T1 segment,increased competition in the rostral pathway may have increasedthe caudal projection of T1 neurons. Finally, when single segments $---$ regardlessof segmental origin $---$ were transplanted to the cervical level wherepreganglionic neurons would encounter no competition, no specificpreference of rostral caudal projections was observed (Yip, 1990).In contrast, when multiple segments were transplanted to the cervicallevel, increased competition among axons from the transplantedneighboring segments could explain why normal projection patternsweremaintained.

Thus the normal segmentally specific projections seen in the sympathetic system may be explained by a competition hypothesis.In the normal embryo, sympathetic preganglionic neurons are restrictedmainly to the thoracic spinal cord, neurons from rostral segmentswill tend to project rostrally for lack of competition from cervicallevels, and neurons from caudal segments will project caudallyfor lack of competition from lumbosacral levels. Neurons fromintervening spinal cord segments will compete with their neighborsfrom both rostral and caudal levels, resulting in rostral andcaudal projections from thesesegments.

Finally, our current view on the development of segmentally specific sympathetic preganglionic projections in the chick canbe summarized as follows. Sympathetic preganglionic axons, alongwith somatic motor axons, exit the spinal cord in the ventralroots. Outside the spinal cord the preganglionic axons are guidedto the sympathetic trunk area. Rostral or caudal preganglionicprojections in the sympathetic trunk, however, are independentof target cues (Yip, 1987) and are not determined intrinsicallyby the segmental origin of the neurons in the spinal cord (Yip,1990; Yip et al., 1998). Instead, they appear to be influencedby the competition of preganglionic axons with each other forfactors in the somiticmesoderm.

  FOOTNOTES

Received Aug. 17, 1998; revised Oct. 8, 1998; accepted Oct. 8, 1998.

This work was supported by National Institutes of Health Grant NS-23916. We thank Tejal Asher, Aderonke Omotade, and NancyVranich for excellent technicalassistance.
Correspondence should be addressed to Dr. Joseph W. Yip, Department of Neurobiology, School of Medicine, University of Pittsburgh,Pittsburgh, PA15261.

  REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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