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Previous Article | Next Article
Volume 16, Number 9, Issue of May 1, 1996 pp. 2901-2911
Copyright ©1996 Society for NeuroscienceDifferential Expression of the p75 Nerve Growth Factor Receptor in Glia and Neurons of the Rat Dorsal Root Ganglia after Peripheral Nerve Transection
Xin-Fu Zhou1, Robert A. Rush1, and Elspeth M. McLachlan2 1 Department of Physiology and Centre of Neuroscience, Flinders University of South Australia, Bedford Park 5042, Australia, and 2 Princes of Wales Medical Research Institute, Randwick, NSW 2031, Australia
ABSTRACT
Sympathetic nerve terminals on blood vessels within the dorsal root ganglia sprout after sciatic nerve lesions in the rat. The mechanism underlying this phenomenon is not clear, but might be predicted to involve nerve growth factor or its homologs because these factors are known to trigger collateral sprouting of undamaged sympathetic noradrenergic terminals. We have found that sciatic nerve lesions lead to a decreased expression of neuronal p75, the low-affinity receptor for the neurotrophins, but an increased expression of glial p75 in ipsilateral dorsal root ganglia. Intriguingly, the increased expression of p75 was found primarily in association with glia surrounding large-diameter neurons, which are those associated with the noradrenergic sprouts. A smaller but significant glial response was also found in contralateral ganglia. The glial response in ipsilateral ganglia could be mimicked by ventral, but not dorsal, root transection. The dorsal root lesion-induced glial responses in contralateral ganglia were greater than those induced by ventral root or sciatic nerve lesions. Combined lesions of dorsal root and either ventral root or sciatic nerve did not prevent the glial responses of ipsilateral ganglia, suggesting that a peripheral signal is involved. Colocalization studies indicate that tyrosine hydroxylase-immunoreactive nerve sprouts were associated with p75-immunoreactive glial cells. Thus, increased glial synthesis of p75 might provide an explanation for the abnormal growth of sympathetic fibers in dorsal root ganglia after peripheral nerve injury.
Key words: satellite cells; glial fibrillary acidic protein; sympathetic; nerve injury; glia; sprouting; tyrosine hydroxylase
INTRODUCTION
Patients with peripheral nerve injuries sometimes suffer from chronic pain that can be relieved by blockade of peripheraladrenoceptors or noradrenaline release (Bonica, 1990
; Jänig and Schmidt, 1992
Many studies have focused on the regulation of neurotrophins and their receptors in Schwann cells (Rush, 1984
Johnson and colleagues (Taniuchi et al., 1986
MATERIALS AND METHODS
Animals. Young adult female Wistar-Kyoto rats were used throughout. All procedures were performed under NH&MRC guidelines, and approval was provided by the institutional Animal Ethics Committee. All surgical procedures were performed under inhalational halothane anesthesia except where indicated below. Three or four rats were used for each of the procedures as follows.Surgery. Nerve lesion paradigms are outlined in the schematic diagrams as shown in Figure 1.
Fig. 1. Schematic diagrams showing different nerve lesion paradigms (see Materials and Methods).
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Sciatic nerve transection. The left sciatic nerve was exposed, ligated at the midthigh level, and cut distal to the ligature. Control rats were treated identically except that the sciatic nerve was exposed but not ligated or transected.
Dorsal rhizotomy. Identification of the L5 dorsal root was achieved by removal of the transverse process and dorsal laminae of vertebra to expose the DRG and associated dorsal root. Fine scissors were used to section the dorsal root 2 mm from the ganglion, taking care to avoid damage to the ventral root.
Ventral root transection. The L5 DRG ventral root was exposed as described above and transected 2 mm from the ganglion. The ventral root was sectioned after approaching from the lateral aspect to avoid damage to the dorsal root.
Combined ventral and dorsal root section. Both ventral and dorsal roots (L5) were transected after their identification by the procedure described above.
Combined sciatic nerve and dorsal root section. In three rats, both the sciatic nerve and the dorsal root were sectioned as described above.
Immunohistochemistry. Rats were allowed to survive for 1, 2, 4, and 8 weeks after the sciatic nerve lesion and 2 weeks after the other lesions. Pentobarbital (80 mg/kg, i.p.) was used to anesthetize the rats before perfusion through the heart with 100 ml of 0.1 M phosphate buffer, pH 7.4, followed by 500 ml of Zamboni's fixative. Both L5 DRGs were dissected and post-fixed in Zamboni's fixative overnight at 4°C. The ganglia were then rinsed in TBS, pH 7.4, soaked in 30% sucrose, and sectioned at 30 µm on a cryostat. p75 immunohistochemistry was performed as described previously (Zhou et al., 1993
For colocalization of p75 with either glial fibrillary acidic protein (GFAP) or tyrosine hydroxylase (TH), DRGs from animals 1 or 2 weeks after sciatic nerve transection were removed, sectioned, and incubated in both mouse monoclonal 192 IgG (2 µg/ml) and rabbit polyclonal antibodies to GFAP (Dako, Carpenteria, CA; 1:1000) or TH (Pel-Freez Biologicals, Rogers, AR; 1:200). Secondary donkey antibodies (Jackson) to mouse IgG (AMCA-labeled) and rabbit IgG (FITC-labeled) were both diluted at 1:50 and applied to sections for 2 hr.
The sections were mounted in buffered glycerol and observed under a fluorescence microscope. DAB sections were mounted in xylene-based medium and observed using bright-field illumination. The number of p75-immunoreactive (-ir) neurons and neurons surrounded by p75-ir glia and nerve fibers (ring structures) were counted in five randomly selected sections from three to four rats in each group. The same sections were then counter-stained with thionin, and the total number of neurons was counted.
RESULTS
Controls
In DRGs of normal rats, ~60% of all neurons were immunoreactive for p75 (see Figs. 2.1, 3). The staining was present in neurons with a wide range of soma sizes, appearing as a granular stain localized to the soma cytoplasm and some nerve fibers (Fig. 2.1). Occasionally, p75-ir was present in glia and nerve fibers surrounding neuronal somata in the shape of ring structures. These ring structures were almost always associated with large-diameter neurons, consistent with previous reports by others and this laboratory (Verge et al., 1989
Fig. 2. Effects of sciatic nerve transection on the expression of p75-ir within L5 DRG. 1, A section from sham-operated rats showing subpopulations of large and small p75-ir neurons. 2, A section from contralateral DRG 8 weeks after sciatic nerve transection showing increased expression of p75-ir in fibers and glia surrounding some large neurons. 3-6, One, two, four, and eight weeks, respectively, after ipsilateral sciatic nerve transection showing decreased expression of p75-ir in neurons and increased expression in nerve bundles and glia. Asterisks indicate a neuron with surrounding ring of immunoreactivity; open arrows indicate clusters of p75-ir glial cells; filled arrows indicate p75-ir nerve bundles. Scale bar, 50 µm.
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Fig. 3. Effect of sciatic nerve transection on the percentage of p75-ir neurons in L5 DRG. The numbers of p75-ir neurons were counted as described in Materials and Methods. The data are plotted as mean ± SEM (n = 4). The percentage of p75-ir neurons was significantly reduced after sciatic nerve transection (asterisks indicate p < 0.05 compared with control).
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Effects of sciatic nerve lesions
Ipsilateral DRGs After sciatic nerve lesions, p75-ir was changed as judged by a number of criteria.(1) One week after injury, the intensity of staining and the number of immunoreactive neuronal cell bodies were significantly reduced (Fig. 2.3), resulting in fewer positive cells (26%) compared with 51% in the intact DRG (Fig. 3). These changes became more marked with time. Only 13% of all neurons were p75-ir by 8 weeks postlesion. In contrast, there were no significant changes from control in the percentages of positive neurons in the contralateral ganglia (Fig. 2.2).
(2) The number of immunoreactive nerve bundles within the ipsilateral DRG increased significantly 1 week after operation and remained elevated for 8 weeks (see filled arrows in Fig. 2.5, 2.6). There was also a slight increase in the same immunoreactive nerve bundles in the contralateral DRG at all times examined (see filled arrow in Fig. 2.2).
(3) After sciatic lesions, p75-ir increased strongly in glia around many primary afferent neurons. This immunoreactivity was in the form of ring-shaped structures, most of which encircled large-diameter neuron somata (see asterisk in Fig. 2). We have observed that clusters of glial cells aggregate around one pole of large sensory neurons and express p75-ir. These p75-ir ring structures appeared similar to the arrangement of catecholamine-containing fibers described in a previous study (McLachlan et al., 1993
Fig. 4. Effect of sciatic nerve transection on the number of p75-ir ring structures surrounding neurons. The neurons surrounded by p75-ir glia or nerve fibers were counted as described in Materials and Methods and are plotted as mean ± SEM (n = 4). The percentage of neurons with ring structures in ipsi- and contralateral DRG after sciatic nerve lesion was significantly increased with postlesion time (asterisks indicate p < 0.05 compared with control).
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(4) Some glia that were in clusters but not surrounding neurons were strongly immunoreactive for p75 after peripheral nerve lesions (see open arrow in 2.6). These glia were usually located between large neurons and also occurred in the contralateral DRGs after sciatic nerve lesion (see open arrow in Fig. 2.2); they were only rarely seen in control DRGs. Cresyl violet staining also showed a significant increase in the number of glial cells surrounding lesioned sensory neurons (data not shown).
Contralateral DRGs
In the contralateral DRGs, similar changes of p75 expression were seen in both nerve bundles and glia, but not in neuronal somata. The number of immunoreactive ring structures was increased significantly at 2 weeks (p < 0.05) and 8 weeks (p < 0.05) after sciatic nerve injury, although their number was always far less than that seen in ipsilateral ganglia (Fig. 4). In contrast to the ipsilateral DRGs, both the number of neuron somata immunoreactive for p75 and the intensity of the stain within each neuron were unaffected by the sciatic nerve lesion.In three rats 2 weeks after sciatic nerve lesions, cervical DRGs (C6) were also examined for p75 expression. These ganglia appeared identical to corresponding ones from control unoperated rats (data not shown).
Colocalization of p75 with GFAP
To test whether the p75-ir was associated with glia, colocalization of p75-ir with the glial cell marker GFAP-ir was performed. After sciatic nerve lesions, a significant increase in GFAP-ir glial cells was seen, particularly surrounding large neurons and in some nerve bundles. As shown in Figure 5, the p75-ir present in ring structures surrounding large neurons and some nerve bundles was colocalized with GFAP-ir in both the ipsilateral (compare Fig. 5.1 with 5.2) and contralateral DRG (compare Fig. 5.3 with 5.4), indicating that a proportion of the p75-ir was localized to both satellite cells (ring structures) and Schwann cells (in nerve bundles). No GFAP-ir was associated with or without p75-ir in neuron somata. GFAP-ir and p75-ir were also colocalized in glial clusters that were not associated with neurons (compare Fig. 5.5 with 5.6). However, some GFAP-ir glia around small-diameter primary afferent neurons were not immunoreactive for p75.
Fig. 5. Colocalization of p75-ir with GFAP-ir in the ipsilateral (panels 1, 2, 5, 6) and contralateral (panels 3, 4) L5 DRG after sciatic nerve transection. Panels 1, 3, and 5 are sections stained with mouse antibodies to p75 followed by AMCA-conjugated secondary antibodies, and panels 2, 4, and 6 are the same sections stained with rabbit antibodies to GFAP followed by FITC-conjugated secondary antibodies. Asterisks indicate neurons immunoreactive for p75 but negative for GFAP-ir; arrowheads in 1-4 indicate large neurons with p75-ir ring structures that were also immunoreactive for GFAP; arrowheads in 5 and 6 indicate clusters of glial cells that are both p75-ir and GFAP-ir; open arrows in 1 and 2 indicate a small neuron without p75-ir ring structure but with GFAP-ir. Scale bars: 1-4 (shown in 2), 100 µm; 5, 6 (shown in 6), 50 µm.
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Effects of ventral root transection on p75 expression
As expected from several previous studies (Koliatsos et al., 1991
Fig. 6. Effects of ventral root, dorsal root, and combined dorsal and ventral root transections on p75-ir in L5 DRGs. 1, A micrograph showing normal expression of p75 in the sham-operated DRGs. 2, A micrograph showing ring structures around large neurons from an animal with an L5 ventral root transection one week earlier. An open arrow indicates intact dorsal root, and an arrowhead indicates lesioned ventral root. 3, 4, Micrographs of the respective ipsi- and contralateral DRG from an animal with a transection of dorsal root of the L5 spinal ganglion one week earlier. Arrowheads in 3 indicate intensely labeled DRG neurons. 5, 6, Micrographs of respective ipsi- and contralateral DRG from an animal with combined lesion of dorsal and ventral root of the L5 spinal ganglion 1 week earlier. Scale bar, 200 µm.
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Table 1. Summary of effects of different nerve lesions on expression of p75 in neurons, glial ring structures, and nerve bundles in the ipsilateral and contralateral DRGs
Lesion Ipsilateral DRG Contralateral DRG N GR NB N GR NB Sci. n. ++++ ++ ++ + DR +/ ++++ +++ + VR ++++ + ++ + DR + VR +++ +++ +++ + DR + Sci. n. ++++ ++++ ++ + The lesion paradigms are schematically shown in Figure 1. Sci. n., sciatic nerve section; VR, ventral root section; DR, dorsal root section; N, neuron; GR, glial ring structures; NB, nerve bundles. Changes were scored as follows: , no change; +/
Fig. 7. Effects of nerve lesions on the numbers of p75-ir ring structures in the DRGs ipsi- and contralateral to the lesions. The surgical procedures were as described in Materials and Methods. Shaded bars, Ipsilateral DRGs; filled bars, contralateral DRGs. Sci. n, Sciatic nerve division; VR, ventral root section; DR, dorsal root section. ANOVA: F = 31.7, p < 0.01; *p < 0.01 compared with control; +p < 0.05 compared with DRG contralateral to sciatic nerve division alone (filled bar).
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Effects of dorsal root transection on p75 expression
In contrast to the sciatic nerve lesions, which triggered a reduction of p75-ir within ipsilateral ganglionic neuron somata, dorsal root lesions induced increases in both the number and the intensity of staining of p75-ir neurons (Fig. 6.3, Table 1). In addition, p75-ir was also increased in the intraganglionic nerve bundles compared with control rats (see Fig. 6.1, Table 1). However, in contrast to the sciatic nerve lesions, the dorsal root lesion triggered a slight significant increase in p75-ir in ganglionic satellite cells. Only 2.2 ± 0.7% of neurons were surrounded with p75-ir glia. In contralateral ganglia, 17.9 ± 1.6% of p75-ir ring structures were observed, a response greater than that after sciatic nerve lesions (p < 0.05; Figs. 6.4, 7, Table 1).Effects of combined dorsal and ventral root transections
To determine whether the signals upregulating p75-ir in satellite cells after ventral root lesions are mediated through the spinal cord and dorsal roots, both ventral and dorsal roots were cut in another group of animals. As shown in Figures 6.5 and 7 and Table 1, the combined lesion did not significantly reduce the number of p75-ir ring structures in the ipsilateral DRG (combined, 27.8 ± 1.9%; ventral root only, 28.9 ± 4.0%), suggesting that the signals inducing these after ventral lesion did not derive from the spinal cord. The p75-ir within primary afferent neurons and nerve bundles, like that after dorsal root lesions only, was also increased markedly by the combined lesion. In comparison with the ventral root or sciatic nerve lesions, the number of ring structures in the contralateral DRGs was significantly increased (22.6 ± 2.0 vs 6.5 ± 1.2%; p < 0.01) but was comparable with the response to dorsal root lesion only (17.9 ± 1.6%). The pattern of p75-ir expressed in the contralateral DRGs (Fig. 6.6) was similar to that seen after ventral or dorsal root lesions only (Table 1).Effect of combined sciatic nerve and dorsal root lesion
To determine whether the signals upregulating p75-ir in satellite cells after sciatic nerve lesion are derived from the spinal cord through the dorsal root, sciatic nerve section was combined with dorsal root section. As shown in Figure 7 and Table 1, the number of ring structures after the combined lesions was comparable with sciatic nerve lesion only (33.5 ± 4.4 vs 32.0 ± 5.1). Similar to changes observed after sciatic nerve lesion only, but in contrast to dorsal root lesion only, p75-ir in sensory neurons was also reduced by the combined lesion (data not shown). In addition, p75-ir in the nerve bundles within the DRGs was also increased. The number of ring structures in the contralateral DRGs was 10.2 ± 1.2%, more than the sciatic nerve lesion only (p < 0.05), but not as high as combined lesions of dorsal and ventral roots (p < 0.05) or dorsal root only (p < 0.05).Colocalization of p75 glial ring structures with TH-ir nerve sprouts
To determine the relationship between glial p75 ring structures and catecholaminergic nerve axons, double labeling of p75 and TH was performed. One week after sciatic nerve lesion, TH-ir fibers were identified within the ipsilateral L4 and L5 DRGs. These fibers were mostly found around large sensory neurons and associated satellite cells (compare Fig. 8.1 with 8.2) or Schwann cells in the nerve bundles (compare Fig. 8.3 with 8.4). Some of these fibers could be traced back to nerve fibers surrounding small blood vessels. TH-ir axons ran over or between p75-ir satellite cells (Fig. 8.1, arrowheads). Because of strong glial p75-ir, it was difficult to determine whether or not TH-ir fibers associated with these glia were also p75-ir. However, where TH-ir fibers were not associated with p75-ir glial cells, they were always themselves p75-ir (compare Fig. 8.5 with 8.6).
Fig. 8. Colocalization of TH-ir axons with p75-ir glia and nerve fibers in ipsilateral DRG 1 week after sciatic nerve lesion. Pairs of micrographs (1, 2; 3, 4; 5, 6) are each of the same section using different filters. Large arrowheads in 1, 3, and 5 indicate TH-ir nerve fibers; small arrowheads in 2 indicate p75-ir satellite cells associated with a large neuron surrounded by TH-ir nerve terminals (1); arrowheads in 4 indicate nerve bundles immunoreactive for p75 in the same site as TH-ir fibers (3); arrowheads in 6 indicate p75-ir colocalized with a TH-ir nerve fiber. Scale bar (shown in 1), 100 µm. In 1, 3, and 5, which show TH-ir fibers, significant autofluorescence of sensory neurons was observed with the filter for FITC.
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DISCUSSION
The present study has revealed differential expression of p75 in neurons and glia in DRGs after sciatic nerve injury. A reduction in p75-ir in cell bodies, consistent with previous histological and biochemical demonstration of mRNAp75 (Sebert and Shooter, 1993p75 expression within DRG neurons appears to be regulated by signals from peripheral tissues, because only lesions that damaged peripheral sensory axons led to the loss of its expression. The regulating signals are not known, but one seems likely to be NGF. NGF increases p75 mRNA in cultured primary afferent neurons in vitro (Lindsay et al., 1990
In contrast, p75 expression in glia after lesions of either the sciatic nerve or the ventral (but not dorsal) roots suggests that its upregulation is associated with damage to motor nerve fibers. The glial cells that respond are mainly those associated with large-diameter primary afferent neurons with low-threshold mechanosensitive endings in the periphery. This increased expression of glial p75 has not been reported previously either for mRNA or by protein analysis of DRGs.
p75 expression in nerve bundles in the DRGs was increased in response to all lesion paradigms, particularly dorsal rhizotomy. The dramatic upregulation after dorsal root lesion resembled that in the distal stump after sciatic nerve lesions in which p75 is also involved in the Schwann cells (Taniuchi et al., 1986
The p75-ir glial rings occurred much more frequently than the rings of noradrenergic terminals observed after similar sciatic lesions (McLachlan et al., 1993
Because the number of GFAP-ir glia within the DRG after lesions was substantially increased, the colocalization of p75-ir with GFAP-ir seen in the present study suggests that upregulation of the receptor is associated with glial proliferation. The signal regulating this response is not known, but it is probably not attributable to factors secreted by invading macrophages (Lu and Richardson, 1991
The lack of a widespread increase in p75 expression, both in the cervical DRGs examined here and in ipsilateral trigeminal ganglia after retrogasserian rhizotomy (Henry et al., 1993
The appearance of glial rings in the contralateral DRG again parallels the contralateral sprouting of sympathetic axons (McLachlan et al., 1993
Possible peripheral mechanisms
Because selective lesions of motor nerve fibers in L5 ventral root mimicked the response to sciatic transection in producing p75-ir rings, direct trauma to primary afferent neurons is not mandatory for this response. Further, lesions of dorsal roots alone had little effect on the appearance of the rings and also failed to block the effects of ventral rhizotomy, indicating that the effects of ventral root section did not occur via the spinal cord. Combined lesions of sciatic nerve and dorsal root also failed to abolish the appearance of rings. Therefore, the p75 glial response within ipsilateral DRGs requires damage of motor nerve fibers.Two possible explanations to account for this phenomenon are as follows. (1) Positive signals may be generated from Schwann cells around degenerating motor axons, which spread to myelinated afferent fibers within the same nerve trunk and signal back to cell bodies in the DRGs. The cell bodies would then release secondary signals to induce glial proliferation (Wen et al., 1994
Is the increased glial expression of p75 involved in noradrenergic sprouting?
This study has shown TH-ir axons associated with p75-ir glial cells. Although sympathetic neurons normally express p75 and their responsiveness to NGF most likely involves this receptor, p75 binds all four neurotrophins with similar affinity (Rodriguez-Tébar et al., 1990Sympathetic neurons express both trkA and trkC, the putative high-affinity receptors for NGF and NT3, respectively, and are responsive to both factors during development in vitro (Hohn et al., 1990
FOOTNOTES
Received Dec. 12, 1995; revised Feb. 7, 1996; accepted Feb. 12, 1996.
This work was supported by grants from the National Health and Medical Research Council of Australia to R.A.R., X.-F.Z., and E.M.M. We are grateful to Dr. E. M. Johnson for providing the 192 antibody.
Correspondence should be addressed to Dr. Xin-Fu Zhou, Department of Physiology and Centre of Neuroscience, Flinders University of South Australia, Bedford Park 5042, Australia.
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