Mechanical properties and fiber type composition of chronically inactive muscles

A role for neuromuscular activity in the maintenance of skeletal muscle properties has been well established. However, the role of activity-independent factors is more difficult to evaluate. We have used the spinal cord isolation model to study the effects of chronic inactivity on the mechanical properties of the hindlimb musculature in cats and rats. This model maintains the connectivity between the motoneurons and the muscle fibers they innervate, but the muscle unit is electrically "silent". Consequently, the measured muscle properties are activity-independent and thus the advantage of using this model is that it provides a baseline level (zero activity) from which regulatory factors that affect muscle cell homeostasis can be defined. In the present paper, we will present a brief review of our findings using the spinal cord isolation model related to muscle mechanical and fiber type properties.

The analgesic action of nitrous oxide is dependent on the release of norepinephrine in the dorsal horn of the spinal cord

BACKGROUND

The authors and others have demonstrated that supraspinal opiate receptors and spinal alpha2 adrenoceptors are involved in the analgesic mechanism for nitrous oxide (N2O). The authors hypothesize that activation of opiate receptors in the periaqueductal gray results in the activation of a descending noradrenergic pathway that releases norepinephrine onto alpha2 adrenoceptors in the dorsal horn of the spinal cord.

METHODS

The spinal cord was transected at the level of T3-T4 in rats and the analgesic response to 70% N2O in oxygen was determined by the tail flick latency test. In a separate experiment in rats a dialysis fiber was positioned transversely in the dorsal horn of the spinal cord at the T12 level. The following day, the dialysis fiber was infused with artificial cerebrospinal fluid at a rate of 1.3 microl/min, and the effluent was sampled at 30-min intervals. After a 60-min equilibration period, the animals were exposed to 70% N2O in oxygen. The dialysis experiment was repeated in animals that were pretreated with naltrexone (10 mg/kg, intraperitoneally) before N2O. In a third series, spinal norepinephrine was depleted with n-(2-chloroethyl)-n-ethyl-2-bromobenzylamine (DSP-4), and the analgesic response to 70% N2O in oxygen was determined.

RESULTS

The analgesic effect of N2O was prevented by spinal cord transection. After exposure to N2O, there was a fourfold increase in norepinephrine released in the first 30-min period, and norepinephrine was still significantly elevated after 1 h of exposure. The increased norepinephrine release was prevented by previous administration of naltrexone. Depletion of norepinephrine in the spinal cord blocked the analgesic response to N2O.

CONCLUSIONS

A descending noradrenergic pathway in the spinal cord links N2O-induced activation of opiate receptors in the periaqueductal gray, with activation of alpha2 adrenoceptors in the spinal cord. N2O-induced release of norepinephrine in the dorsal horn of the spinal cord is blocked by naltrexone, as is the analgesic response. Spinal norepinephrine is necessary for the analgesic response to the N2O.

Adenoviral vector-mediated expression of a foreign gene in peripheral nerve tissue bridges implanted in the injured peripheral and central nervous system

Axons of the CNS do normally not regenerate after injury, in contrast to axons of the PNS. This is due to a different microenvironment at the site of the lesion as well as a particular intrinsic program of axonal regrowth. Although transplantation of peripheral nerve tissue bridges is perhaps the most successful approach to promoting regeneration in the CNS, ingrowth of CNS nerve fibers with such transplants is limited. Genetic modification of peripheral nerve bridges to overexpress outgrowth-promoting proteins should, in principle, improve the permissive properties of peripheral nerve transplants. The present study shows that pieces of peripheral intercostal nerve, subjected to ex vivo adenoviral vector-mediated gene transfer and implanted as nerve bridges in transected sciatic nerve, avulsed ventral root, hemi-sected spinal cord and intact brain, are capable of expressing a foreign gene. In vitro studies showed expression of the reporter gene LacZ up to 30 days in Schwann cells. After implantation, LacZ expression could be detected at 7 days postimplantation, but had virtually disappeared at 14 days. Schwann cells of the transduced nerve bridges retained the capacity of guiding regenerative peripheral and central nerve fiber ingrowth. Transduction of intercostal nerve pieces prior to implantation should, in principle, enable enhanced local production of neurotrophic factors within the transplant and has the potential to improve the regeneration of injured axons into the graft.

Regeneration of transected spinal cord in young adult rats using freeze-dried alginate gel

We have recently reported that freeze-dried alginate gel, which was developed in our laboratory, enhanced peripheral nerve regeneration. The purpose of this study was to examine whether alginate gel is capable of promoting nerve regeneration in the severed spinal cord of adult mammals. Using Wistar rats at 30 days of age (P30), the T9-T10 spinal cord was totally resected and alginate gel was implanted across the gap. Forty-five days after surgery myelinated and unmyelinated axons regenerated throughout the gap with remaining alginate gel. The elongated axons established electrophysiologically functional projections across the gap. In conclusion, freeze-dried alginate gel could be a promising material as an artificial nerve guide for repair of injured central nervous system.

Persistence of hybrid fibers in rat soleus after spinal cord transection

The effects of a chronic (up to 360 days) reduction in neuromuscular activity (defined as electrical activation and loading) on myosin heavy chain (MHC) isoform expression in the rat soleus muscle were studied. A complete mid-thoracic (T7-T8) spinal cord transection (ST) was used to induce a reduction in soleus muscle neuromuscular activity. Electrophoretic analyses revealed that MHC-I was progressively decreased after ST, accounting for approx. 90% of the total soleus MHC in controls and only approx. 12% 1 year after ST. The reductions in the proportion of MHC-I were countered by increases in MHC-IIa and MHC-IIx with the increase in MHC-IIx preceding the increase in MHC-IIa. Curiously, MHC-IIb was expressed only at very low levels. Thus, a complete transformation from predominantly MHC-I to MHC-IIb did not occur. Many fibers (up to approx. 80%) contained multiple MHCs (hybrid fibers) after ST. The proportion of hybrid fibers was maintained at a high level (approx. 50%) 1 year after ST. These data suggest that: 1) a prolonged reduction in neuromuscular activity was not sufficient to induce high level MHC-IIb expression by the soleus muscle; and 2) hybrid fibers were not simply transitional fibers. Thus, it appears that under appropriate conditions hybrid fibers may represent a "stable" fiber phenotype.

NGF levels decrease in the spinal cord and dorsal root ganglion after spinal hemisection

To examine changes in nerve growth factor (NGF) levels in spinal cord and dorsal root ganglia (DRG) after spinal injury, male Sprague-Dawley rats weighing 150-175 g were given spinal hemisections. NGF content was measured at various post-surgical times and compared with naive controls (n = 4 per time point) in the spinal cord, DRG and blood serum by ELISA techniques (Promega). Levels of NGF in the blood serum were significantly increased 8-fold at 48h but were significantly decreased in the spinal cord and DRG by 2- to 4-fold until 7 days postsurgery (ANOVA, p < 0.05). Contrary to accepted dogma, spinal injury results in decreased levels of NGF in the spinal cord and DRG following spinal injury.

Congenital kyphosis in myelomeningocele. The effect of cordotomy on bladder function

To determine the effect of cordotomy on the function of the bladder during surgical correction of congenital kyphosis in myelomeningocele, we reviewed 13 patients who had this procedure between 1981 and 1996. The mean age of the patients at operation was 8.9 years (3.7 to 16) and the mean follow-up was 4.8 years (1.3 to 10.8). Bladder function before and after operation was assessed clinically and quantitatively by urodynamics. The mean preoperative kyphosis was 117 degrees (52 to 175) and decreased to 49 degrees (1 to 89) immediately after surgery. At the latest follow-up, a mean correction of 52% had been achieved. Only one patient showed deterioration in bladder function after operation. Eight out of the nine patients who had urodynamic assessment had improvement in bladder capacity and compliance, and five showed an increase in urethral pressure. One patient developed a spastic bladder and required subsequent surgical intervention. Cordotomy, at or below the level of the kyphosis, allows excellent correction of the structural deformity.

Spinal integration of antidromic mediated cutaneous vasodilation during dorsal spinal cord stimulation in the rat

The purpose of this study was to determine the involvement of supraspinal centers and spinal synaptic integration in cutaneous vasodilation mediated by dorsal spinal cord stimulation (DCS). Laser Doppler flowmetry was used to assess cutaneous blood flow changes in the rat hindpaw during DCS with a unipolar ball electrode placed at the L2-L3 spinal level. Results demonstrated that transecting the spinal cord at the T10 spinal segment did not alter the DCS response while T13 spinal transection abolished the DCS-induced vasodilation. Inhibition of synaptic activity with topical application of muscimol (0.2 mM) on the dorsal surface of the spinal cord markedly attenuated the DCS response. In conclusion DCS-induced vasodilation involved synaptic integration but did not require input from rostral spinal sites or supraspinal areas.

[Induction of noradrenergic supersensitivity following cordotomy in neonatal rat spinal motoneurons]

Patients with spinal cord lesions frequently show autonomic hyperreflexia. The mechanism of autonomic hyperreflexia has been thought to be an acute general autonomic overactivity in response to cutaneous or visceral stimuli, but it remains uncertain. Several kinds of experiments suggest that amplified spinal sympathetic reflexes in the decentralized cord are attributable to the denervation supersensitivity of denervated neurons, which is a well-known phenomenon in denervated muscle fibers. In the present study, changes in the supersensitivity of motoneurons after cordotomy were studied in the spinal cord of neonatal rats. Responses to bath-applied noradrenaline (NA) were recorded from a ventral root of the isolated spinal cord of 6-day-old rats. In normal spinal cords, NA induced depolarization in motoneurons dose-dependently. alpha 1-antagonist prazosin (3 microM) inhibited the deporalization induced by NA, and alpha 2-antagonist rauwolscine (1 microM) potentiated it. In one group of rats, cordotomy was performed 4 days after birth by complete transection of the spinal cord at vertebrate 8th-10th thoracic level, and NA response was examined two days later (when they were 6 days old). In cordotomized rats, NA-induced depolarization was increased with respect to both amplitude and duration. alpha 1- as well as alpha 2-antagonists inhibited the NA response in the spinalized rats. Especially, both antagonists shortened the duration of NA response as compared to normal level. It is concluded that the denervation supersensitivity to NA appears 2 days after cordotomy in the spinal motoneurons of neonatal rats and that the supersensitivity to NA is attributable to the upregulation of both alpha 1- and alpha 2-adrenoceptors on the motoneurons, indicating that a new type of alpha 2-adrenoceptor function appears.

Uterine contractility and blood flow are reflexively regulated by cutaneous afferent stimulation in anesthetized rats

The effects of cutaneous mechanical afferent stimulation of various skin areas on uterine contractility and blood flow were examined in anesthetized non-pregnant rats. The contractility of the uterus was measured by the balloon method in the uterus. The uterine blood flow was measured by laser Doppler flowmetry. Noxious pinching stimulation of the perineum for 1 min induced an abrupt contraction of the uterus during stimulation. Pinching of a hindpaw or perineum and innocuous brushing of the perineum for 1 min increased uterine blood flow. Stimulation of other skin areas produced no changes in uterine contractility or blood flow. Most uterine responses were abolished by severance of the pelvic nerves, which innervated the uterus. The activity of pelvic parasympathetic efferent nerves to the uterus increased following perineal pinching. All these cutaneous stimulation-induced responses of uterine contractility, blood flow and pelvic efferent nerve activity still existed, and were even augmented, after acute spinalization. These results indicate that cutaneous mechanical sensory stimulation can regulate uterine contractility and blood flow by a segmental spinal reflex mechanism via uterine parasympathetic efferent nerves.

Oligodendroglial reaction following spinal cord injury in rat: transient upregulation of MBP mRNA

The reaction of oligodendrocytes in response to traumatic injury of the CNS are poorly understood. In the present report we studied changes in the expression of a major constituent of CNS myelin, myelin basic protein (MBP), by immunohistochemistry and in situ hybridization from 6 h up to 2 weeks following partial transection of the spinal cord in adult rats. MBP immunohistochemistry showed degeneration of myelin at the lesion center and signs of myelin breakdown in necrotic foci in the dorsal and ventral funiculi proximal and distal to the lesion. In situ hybridization revealed that mRNA for MBP was downregulated at the local lesion site within the first day following injury, probably reflecting oligodendrocytes to undergo cell death. From 2 days on, however, MBP mRNA was conspicuously upregulated at the border of the lesion area. This "reactive" response of surviving oligodendrocytes, as indicated by increased levels of MBP mRNA, peaked around 8 days. At this time, oligodendrocytes displaying strong MBP in situ signal formed stripe-like structures which were oriented radially toward the lesion center and arranged in parallel to neurofilament-positive axons. At around 2 weeks post-injury, MBP mRNA at the border of the lesion area was again downregulated to levels comparable to uninjured controls. These results show that traumatic injury of the spinal cord induces a "reactive" response of surviving oligodendrocytes adjacent to lesion sites. This response might represent an important component of local repair mechanisms.

Spinal cord transection induced c-fos protein in the rat motor cortex

Spinal cord transection at the middle thoracic level induced the expression of c-Fos protein in the rat motor cortex detected with the immunohistochemical study. At 1 h after transection, maximal expression of c-Fos was seen in the frontal cortex and hindlimb area of the cortex. c-Fos-like immunoreactive neurons were recognized in the second to sixth layers of these cortices, although the axotomized neurons were located only in the fifth layer of these cortices. A significant difference of c-Fos-like protein expression was observed between the spinal transected group and the sham operated group 1 h after the operation. These results indicate that each layer of the motor cortical column is activated and that there is a correlation between alteration of the neuronal network and functional plasticity.

Adult opossums (Didelphis virginiana) demonstrate near normal locomotion after spinal cord transection as neonates

When the thoracic spinal cord of the North American opossum (Didelphis virginiana) is transected on postnatal day (PD) 5, the site of injury becomes bridged by histologically recognizable spinal cord and axons which form major long tracts grow through the lesion. In the present study we asked whether opossums lesioned on PD5 have normal use of the hindlimbs as adults and, if so, whether that use is dependent upon axons which grow through the lesion site. The thoracic spinal cord was transected on PD5 and 6 months later, hindlimb function was evaluated using the Basso, Beattie, and Bresnahan (BBB) locomotor scale. All animals supported their weight with the hindlimbs and used their hindlimbs normally during overground locomotion. In some cases, the spinal cord was retransected at the original lesion site or just caudal to it 6 months after the original transection and paralysis of the hindlimbs ensued. Surprisingly, however, these animals gradually recovered some ability to support their weight and to step with the hindlimbs. Similar recovery was not seen in animals transected only as adults. In order to verify that descending axons which grew through the lesion during development were still present in the adult animal, opossums subjected to transection of the thoracic cord on PD5 were reoperated and Fast blue was injected several segments caudal to the lesion. In all cases, neurons were labeled rostral to the lesion in each of the spinal and supraspinal nuclei labeled by comparable injections in unlesioned, age-matched controls. The results of orthograde tracing studies indicated that axons which grew through the lesion innervated areas that were appropriate for them.

Roles of ascending inhibition during two rhythmic motor patterns in Xenopus tadpoles

We have investigated the effects of ascending inhibitory pathways on two centrally generated rhythmic motor patterns in a simple vertebrate model, the young Xenopus tadpole. Tadpoles swim when touched, but when grasped respond with slower, stronger struggling movements during which the longitudinal pattern of motor activity is reversed. Surgical spinal cord transection to remove all ascending connections originating caudal to the transection (in tadpoles immobilized in alpha-bungarotoxin) did not affect "fictive" swimming generated more rostrally. In contrast, cycle period and burst duration both significantly increased during fictive struggling. Increases were progressively larger with more rostral transection. Blocking caudal activity with the anesthetic MS222 (pharmacological transection) produced equivalent but reversible effects. Reducing crossed-ascending inhibition selectively, either by midsagittal spinal cord division or rostral cord hemisection (1-sided transection) mimicked the effects of transection. Like transection, both operations increased cycle period and burst duration during struggling but did not affect swimming. The changes during struggling were larger with more rostral hemisection. Reducing crossed-ascending inhibition by spinal hemisection also increased the rostrocaudal longitudinal delay during swimming, and the caudorostral delay during struggling. Weakening inhibition globally with low concentrations of the glycine antagonist strychnine (10-100 nM) did not alter swimming cycle period, burst duration, or longitudinal delay. However, strychnine at 10-60 nM decreased cycle period during struggling. It also increased burst duration in some cases, although burst duration increased as a proportion of cycle period in all cases. Strychnine reduced longitudinal delay during struggling, making rostral and caudal activity more synchronous. At 100 nM, struggling was totally disrupted. By combining our results with a detailed knowledge of tadpole spinal cord anatomy, we conclude that inhibition mediated by the crossed-ascending axons of characterized, glycinergic, commissural interneurons has a major influence on the struggling motor pattern compared with swimming. We suggest that this difference is a consequence of the larger, reversed longitudinal delay and the extended burst duration during struggling compared with swimming.

Long term effects of spinal cord transection in zebrafish: swimming performances, and metabolic properties of the neuromuscular system

This study concerns functional recovery of zebrafish following spinal cord transection. Spinal cords were transected at the level of the 14th vertebra, just rostral to the dorsal fin. Recovery was tested at one month after transection when descending fibers start to regrow across the transection site and at three months after transection when fish perform kick and glide swimming. To estimate the rate of regrowth across the lesion site we analysed the tyrosine hydroxylase (TH) and dorsal 5-hydroxytryptamine (5-HT) systems in distal parts of lesioned cords. Both systems have cell bodies in the brainstem and in control fish TH- and dorsal 5-HT-containing fibers descend to all spinal segments. Swimming performance was studied by subjecting lesioned fish to endurance tests in a swimming tunnel with water flowing at a constant rate of 2 or 4.5 body lengths per second (BL/s). At 2 BL/s slow myotomal muscles are active whereas at 4.5 BL/s fast myotomal muscles are recruited. Control fish endured sustained swimming at both speeds for at least 3 hours. As a measure for the condition of the neuromuscular system in trunk and tail, we analysed aerobic metabolic capacities, assessed by NADH-tetrazolium reductase (NADH-TR) histochemistry of myotomal muscle fibers and spinal lateral neuropil. We found that TH- and dorsal 5-HT-immunoreactive fibers were absent in the entire distal part of lesioned cords at one month but at two months after transection they were present at approximately 6000 microns caudally to the site of the lesion. Thus the rate of outgrowth of these fibers is at least 200 microns per day. Sustained swimming at the slow speed (2 BL/s) could be endured for about 14.4 min at one month and for 23.5 min at two months after transection; there was no further improvement in the period that followed. In contrast, in the 10 weeks following transection, fast swimming (4.5 BL/s) could be endured for about 5 to 6 minutes. A significant improvement was gained in the period of 10 to 12 weeks after transection when fish could endure the high speed for almost 15 min. The aerobic capacity of muscle fibers in distal parts of the body was not strongly affected by the lesion. The only important change in aerobic capacity was observed in the neuropil of distal parts of the cords where, at three months after transection, NADH-TR activity was increased to approximately 150% of control values. On the basis of our findings, we assume that it is not the condition of the neuromuscular system, but rather a deficient co-ordination between proximal and distal body parts of lesioned fish that accounts for the relatively poor performances in endurance tests. Furthermore, differences in timing of improvements in swimming at 2 and 4.5 BL/s indicate that the spinal circuitries serving the slow parts of the neuromuscular system recover at an earlier stage than those serving the fast parts.

Changes in the synaptology of spinal motoneurons in zebrafish following spinal cord transection

Effects of spinal cord transection on the synaptology of zebrafish spinal motoneurons were studied. The transection was made at the level of the 14th vertebra and the synaptology of motoneuron somata and dendrites was analysed at the level of the 21st to the 23rd vertebrae at one month and three months after transection. Horseradish peroxidase, applied to the myotomal muscle, was used to label motoneuron somata and dendritic branches in central and in lateral areas of the neuropil (referred to as central and lateral dendritic profiles). Boutons impinging on motoneurons were classified according to the morphology of the vesicles. We discerned R-boutons with spherical vesicles, F-boutons with flat vesicles and DC-boutons with at least one dense core vesicle. The apposition lengths of R-, F- and DC-boutons and the circumference of labelled profiles were determined to assess the proportional covering of boutons on somata and dendrites. Ratio's of covering with R- and F-boutons (R/F ratio) for somata, central and lateral dendritic profiles were 1.1, 2.1, and 2.1 in control fish and 0.5, 0.5 and 0.9 in lesioned fish at one month after transection, respectively. The total covering of motoneurons in lesioned fish was decreased by 20% on somata and by 30% on lateral dendritic profiles, whereas central dendritic profiles did not change significantly. At three months after transection the R/F ratio's for somata, central and lateral dendritic profiles were 0.5, 0.7 and 0.6, respectively. The total covering on somata and central and lateral dendritic profiles was at control levels. The anatomical aspects of the changes in synaptology indicate that in control fish 50 to 60% of the R-boutons on the motoneuron surface originate from descending axons. In contrast, almost all F-boutons seem to be from local origin.

Reconstruction of flexor/extensor alternation during fictive rostral scratching by two-site stimulation in the spinal turtle with a transverse spinal hemisection

Analyses of fictive scratching motor patterns in the spinal turtle with transverse hemisection provided support for the concept of bilateral shared spinal cord circuitry among neurons responsible for generating left- and right-side rostral, pocket, and caudal fictive scratching. Rhythmic bursts of hip flexor activity, the hip extensor deletion variation of fictive rostral scratching, were elicited by ipsilateral stimulation in the rostral scratch receptive field of a spinal turtle [transection at the segmental border between the second (D2) and third (D3) postcervical spinal segments] with a contralateral transverse hemisection one segment anterior to the hindlimb enlargement (at the D6-D7 segmental border). In addition, other sites were stimulated in this preparation: (1) contralateral sites in a rostral, pocket, or caudal scratch receptive field or (2) ipsilateral sites in a caudal scratch receptive field. A reconstructed fictive rostral scratch motor pattern of rhythmic alternation between hip flexor and hip extensor activation was produced by simultaneous stimulation of one site in the ipsilateral rostral scratch receptive field and another site in one of the other scratch receptive fields. This reconstructed rostral scratch motor pattern resembled the normal rostral scratch motor pattern produced by one-site rostral scratch stimulation of a spinal turtle (D2-D3 transection) with no additional transections. The observation of a reconstructed rostral scratch motor pattern produced by two-site stimulation in the spinal turtle with transverse hemisection supports the concept that hip extensor circuitry activated by stimulation of other scratch receptive fields is shared with circuitry activated by ipsilateral rostral scratch receptive field stimulation.

Development of walking, swimming and neuronal connections after complete spinal cord transection in the neonatal opossum, Monodelphis domestica

Development of coordinated movements was quantitatively assessed in adult opossums (Monodelphis domestica) with thoracic spinal cords transected by (1) crushing 7-8 d after birth [postnatal days 7-8 (P7-P8)]; at 2-3 years of age, systematic behavioral tests (e.g., climbing, footprint analysis, and swimming) showed only minor differences between control (n = 5) and operated (n = 10) animals; and (2) cutting on P4-P6; at 1 month these opossums exhibited coordinated walking movements but were unable to right themselves from a supine position, unlike controls (n = 6). When tested at 2 or 6 months, they could right themselves and showed remarkable coordination, albeit with more differences from controls than after a crush. No animals with spinal cords that were crushed at P14-18 survived because of cannibalism by the mother. Morphological studies (n = 10) 3 months-3 years after crush at 1 week showed restoration of structural continuity and normal appearance at the lesion site. Animals with cut rather than crushed cords showed continuity but greater morphological deficits. That lesions were complete was demonstrated by examining morphology and nerve impulse conduction immediately after crushing or cutting the spinal cord in controls. After lumbar spinal cord injection of 10 kDa dextran amine, retrogradely labeled cells were found rostral to the lesion in hindbrain and midbrain nuclei. Conduction was restored across the site of the lesion. Thus complete spinal cord transection in neonatal Monodelphis was followed by development of coordinated movements and repair of the spinal cord, a process that included development of functional connections by axons that crossed the lesion.

Central regulation of sympathetic ganglia development: heterogeneous response of paravertebral, prevertebral, and terminal ganglia

These studies expand previous observations regarding the central control of neuronal maturation and indicate that paravertebral, prevertebral, and terminal ganglia are all under central influences, but in varying degrees. These variations are probably related to the relative contributions that central pathways exert on specific peripheral neuronal populations during growth and development as well as the various roles of more peripheral developmental modulators such as target organs and hormones, especially in the case of the HG. It is apparent, therefore, that during development central injury may result in heterogeneous deficits depending on the unique intrinsic and extrinsic environment that each ganglion population shares.

Regenerating and sprouting axons differ in their requirements for growth after injury

After spinal cord injury at birth, axotomized brainstem-spinal and corticospinal neurons are capable of permanent regenerative axonal growth into and through a fetal spinal cord transplant placed into the site of either a spinal cord hemisection or transection. In contrast, if fetal tissue which is not a normal target of the axotomized neurons (embryonic hippocampus or cortex) is placed into a neonatal spinal cord hemisection, brainstem-spinal serotonergic axons transiently innervate the transplant, but subsequently withdraw. The first set of experiments was designed to test the hypothesis that after spinal cord transection, serotonergic axons would cross the nontarget transplant, reach normal spinal cord targets caudal to the transection, and gain access to requisite target-derived cues, permitting permanent maintenance. Surprisingly, after a complete spinal cord transection, brainstem-spinal axons failed to grow into an inappropriate target even transiently. These observations suggest that the transient axonal ingrowth into nontarget transplants may represent lesion-induced axonal sprouting by contralateral uninjured axons. We have used double-labeling with fluorescent dyes, to test directly whether axonal sprouting of neurons which maintain collaterals to uninjured spinal cord targets (1) provide the transient ingrowth of brainstem-spinal axons into a nontarget transplant and (2) contribute to permanent ingrowth into target-specific transplants. Uninjured red nucleus, raphe nucleus, and locus coeruleus neurons extend axons into the nontarget transplant while maintaining collaterals to the host spinal cord caudal to the transplant. The lesion-induced sprouting by uninjured axons was also observed with a target-specific transplant. Taken together, these studies suggest that sprouting and regenerating axons may differ in their requirements for growth after injury.

c-Jun expression in adult rat dorsal root ganglion neurons: differential response after central or peripheral axotomy

The response of the mature central nervous system (CNS) to injury differs significantly from the response of the peripheral nervous system (PNS). Axotomized PNS neurons generally regenerate following injury, while CNS neurons do not. The mechanisms that are responsible for these differences are not completely known, but both intrinsic neuronal and extrinsic environmental influences are likely to contribute to regenerative success or failure. One intrinsic factor that may contribute to successful axonal regeneration is the induction of specific genes in the injured neurons. In the present study, we have evaluated the hypothesis that expression of the immediate early gene c-jun is involved in a successful regenerative response. We have compared c-Jun expression in dorsal root ganglion (DRG) neurons following central or peripheral axotomy. We prepared animals that received either a sciatic nerve (peripheral) lesion or a dorsal rhizotomy in combination with spinal cord hemisection (central lesion). In a third group of animals, several dorsal roots were placed into the hemisection site along with a fetal spinal cord transplant. This intervention has been demonstrated to promote regrowth of severed axons and provides a model to examine DRG neurons during regenerative growth after central lesion. Our results indicated that c-Jun was upregulated substantially in DRG neurons following a peripheral axotomy, but following a central axotomy, only 18% of the neurons expressed c-Jun. Following dorsal rhizotomy and transplantation, however, c-Jun expression was upregulated dramatically; under those experimental conditions, 63% of the DRG neurons were c-Jun-positive. These data indicate that c-Jun expression may be related to successful regenerative growth following both PNS and CNS lesions.

Glial changes in the phrenic nucleus following superimposed cervical spinal cord hemisection and peripheral chronic phrenicotomy injuries in adult rats

The objective of the present study was to characterize the microglial and astroglial reaction in the phrenic nucleus following either an ipsilateral C2 spinal cord hemisection, a peripheral phrenicotomy, or a combination of the two injuries in the same adult rat. The present study used three different fluorescent markers and a confocal laser image analysis system to study glial cells and phrenic motoneurons at the light microscopic level. Young adult female rats were divided into one combined injury group (left phrenicotomy and left C2 spinal hemisection with periods of 1 to 4 weeks between injuries, N = 12) and three other groups consisting of noninjured animals (N = 3), animals that received C2 hemisection only (N = 3), and animals with phrenicotomy only (survival periods of 2 (N = 3) and 4 (N = 3) weeks after phrenicotomy). Fluorogold was injected into the diaphragm to label phrenic motoneurons in all animals. Microglia and astrocytes were labeled with Texas red and fluorescein, respectively, and were visualized simultaneously along with phrenic motoneurons. The results suggest that the microglial and astrocytic response in the superimposed injury model are similar to the glial reactions characteristically seen in a peripheral axotomy alone model. These reactions include proliferation and migration of microglial cells along the perineuronal surface (peaking at 2 weeks) and the hypertrophy of astrocytes (peaking at 4 weeks). In addition, the increase in astrocytic tissue, which is characteristically seen in response to axotomy alone, is significantly enhanced in the superimposed injury model. Also, there is a large and rapid increase in GFAP-positive astrocytes within 24 hours after hemisection alone. The information gained from the present study will aid in determining, predicting, and eventually manipulating central nervous system responses to multiple injuries with the objective of reestablishing function in the damaged CNS.

Chronic hypoxia does not induce synaptic plasticity in the phrenic nucleus

Interruption of the main descending respiratory drive to phrenic motoneurons by cold block or spinal cord hemisection results in morphological modifications of the ipsilateral phrenic nucleus in the rat. The modifications consist of an increase in the number of multiple synapses and dendrodendritic appositions and elongation of the asymmetric and symmetric synaptic active zones. Hemisection and hemispinalization by cold block cause not only "functional deafferentation" of the ipsilateral phrenic neurons (i.e., a loss of ipsilateral descending respiratory drive), but also an increase in the remaining contralateral descending respiratory drive. The contralateral respiratory pathways connect with phrenic motoneurons ipsilateral to cold block or hemisection by decussating collateral axons which cross the spinal cord midline below the hemisection/cold block site. Thus, the phrenic nucleus synaptic plasticity could possibly be induced by functional deafferentation or by an increase of the descending respiratory drive. To differentiate between these two possible inducers of the plasticity, we assessed the synaptic morphology of the phrenic nucleus of nonoperated rats exposed to 48 h of hypoxia in an atmosphere chamber. The hypoxia exposure produces an increased descending respiratory drive without functional deafferentation. The quantitative data extracted from electron micrographs of the phrenic nucleus from four experimental rats were compared with the data from four normal breathing animals. Phrenic nucleus morphometric analysis showed that there was no significant difference in the mean number of single synapses between the samples from control animals (141 +/- 12.12) and the experimental animals (156 +/- 26.73). Similarly, no significant difference was detected in the total number of synaptic active zones of control animals (178.25 +/- 11.13) and experimental animals (195.05 +/- 5.35). Furthermore, the length of synaptic active zones of asymmetrical synapses (0.21 +/- 0.024 micron) or symmetrical synapses (0.22 +/- 0.022 micron) did not change significantly compared to the synaptic active zone length in control animals (0.21 +/- 0.018 micron for asymmetrical and 0.21 +/- 0.010 micron for symmetrical). We conclude that no synaptic plasticity occurs in the phrenic nucleus without functional deafferentation in spite of an increase in descending respiratory drive. Therefore functional deafferentation may be the primary inducer of phrenic nucleus synaptic plasticity occurring after hemisection or cold block.

Axotomized rubrospinal neurons rescued by fetal spinal cord transplants maintain axon collaterals to rostral CNS targets

Neurons that maintain extensive axon collaterals proximal to the site of axotomy may be better able to survive injury. Early lesions of the rubrospinal tract lead to retrograde cell death of the majority of axotomized immature neurons. Transplants of fetal spinal cord tissue rescue axotomized rubrospinal neurons and promote their axonal regeneration. Rubrospinal neurons develop many of their axon collaterals postnatally. The present study tests the hypothesis that the axotomized rubrospinal neurons that are rescued by transplants and regenerate their axons are those neurons that have established axon collaterals to targets rostral to the lesion. Neonatal rats received a transplant of fetal spinal cord tissue placed into a midthoracic spinal cord hemisection. One month after transplantation, the retrogradely transported fluorescent tracers fast blue (FB) and diamidino yellow (DY) were used to identify rubrospinal neurons with collaterals to particular targets. FB was injected either into the interpositus nucleus of the cerebellum or into the gray matter of the cervical enlargement to identify collaterals to these targets, and DY was injected into the spinal cord approximately 5 mm caudal to the transplant and lesion site to label retrogradely the neurons that regenerated their axons. Double labeling was observed in the axotomized neurons of the red nucleus after tracer injections into the cervical spinal cord but not after injections into the cerebellum. This labeling pattern indicates that axotomized rubrospinal neurons that are rescued and regenerate axons caudal to the transplant maintain axon collaterals at cervical spinal cord levels. Cerebellar collaterals do not appear to play a role in the survival and regrowth of axotomized rubrospinal neurons.