Functional changes in undamaged sciatic nerves and spinal cord of mice following nerve damage

The state of the contralateral neuromotor apparatus of the rat in conditions of unilateral tenotomy

The effects of unilateral transection of the Achilles tendon (tenotomy) on the electromyographic characteristics of the gastrocnemius muscle on the contralateral side were studied in rats. Motor responses, reflex responses, and motor unit spike activity in the contralateral gastrocnemius muscle were studied in baseline conditions and on afferent stimulation before and 10 days after tenotomy. Changes in the nature of motor unit spike activity and responses to afferent stimulation were observed. The results obtained here demonstrate increases in the excitability of individual motoneurons in the contralateral motor center of the gastrocnemius muscle after exclusion of the symmetrical gastrocnemius muscle from the overall pattern of movement activity.

Effects of peripheral axotomy on neuropeptides and nitric oxide synthase in dorsal root ganglia and spinal cord of the guinea pig: an immunohistochemical study

The effect of axotomy (3, 10 and 21 days) on the expression of some neuronal markers was analysed in dorsal root ganglia and spinal cord of guinea-pigs using immunohistochemistry. Three weeks following injury, substance P-like immunoreactivity (-LI) was slightly reduced in the DRGs of the ipsilateral side, whereas a marked increase in neuropeptide Y(NPY)-LI could be detected ipsilaterally and a smaller increase contralaterally. NPY-LI was mainly expressed in small, but also some medium-sized and large neuron profiles after axotomy. Galanin-LI showed a moderate bilateral increase. No significant changes could be observed in DRGs for calcitonin gene-related peptide (CGRP)-, vasoactive intestinal polypeptide-, peptide histidine isoleucine- or nitric oxide synthase-LIs. In the ventral horn CGRP-LI was slightly increased bilaterally in motoneurons, most pronounced on the injured side. Autotomy behaviour was seen in seven of the nine animals in the twenty-one day group. The present results demonstrate that also in guinea-pigs several peptides undergo distinct changes in their expression after peripheral nerve injury. However, in contrast to rats and monkeys, galanin-LI is only moderately increased in guinea-pigs. Neuropeptide Y showed a dramatic increase mainly in small neurons, in contrast to the upregulation in large neurons in the rat. Thus, distinct species differences exist with regard to the cellular response to nerve injury.

Changes in sciatic nerve and spinal cord function induced by a CNS viral infection

Electrophysiologic response characteristics of mouse sciatic nerve and spinal cord were investigated following CNS infection with the temperature-sensitive (ts) vesicular stomatitis virus (VSV) mutant G31 KS5. Measurements were obtained before clinical symptoms of the virus-induced CNS disease appeared. Sciatic nerve peak conduction velocities were not different between virus and control inoculated groups. For all control groups, sciatic nerve response (SNR) recovery, characterized by the amplitude ratio of double pulse-evoked responses, followed a facilitation-depression time course. By 4 days after VSV inoculation, the time course of SNR recovery changed with the SNR amplitude ratios significantly depressed compared to control. Crossed spinal responses (CSRs) were measured from one sciatic nerve in response to stimulation of the contralateral sciatic nerve. For all control groups, CSR recovery, as characterized by area ratios calculated from single and double pulse evoked responses, followed a facilitation-depression time course. By 5 days after VSV inoculation, the time course of CSR recovery changed with the CSR area ratios significantly depressed compared to control. The results show that simple electrophysiologic techniques can be used to detect virus-induced changes in sciatic nerve and spinal cord previously undetectable by clinical measures.

Immunosuppression in nerve allografting: is it desirable?

Immunologically incompatible sciatic nerve grafts were inserted into the severed sciatic nerves of Wistar rats. In an attempt to induce graft tolerance, low-dose cyclosporin A (CsA) was administered to some animals for 20 weeks, then gradually withdrawn. Behavioural, electrophysiological and histological studies indicated that some degree of regeneration took place in all animals regardless of treatment. Neither a daily dose of 5 mg/kg nor 10 mg/kg was sufficient to prevent the rejection and subsequent disruption of allograft structure, and as a consequence reinnervation of the distal stump was limited. This was manifest both in the poor functional recovery of the denervated foot, and in the large number of regenerated axons found outside of the perineurial membranes of the transplanted fascicles. Therefore, tolerance was not induced at these doses. Furthermore, the significant decrease in the amplitude of electromyographs recorded from experimental and unoperated (control) animals suggests CsA may have a deleterious effect on unlesioned nerve even at these low doses. It would be prudent, therefore, to exercise caution in the combined use of nerve allografts and CsA immunosuppression, until the neurotoxicity of CsA has been investigated further. This is particularly important since CsA is sometimes used in the treatment of certain neuropathic autoimmune diseases.

Relationship between autotomy behaviour and spinal cord monoaminergic levels in rats

In the rat, unilateral neurectomy of the sciatic and saphenous nerves causes autotomy, a self-mutilation behaviour, against the denervated limb that is variable in both its onset and severity. To study some of the possible neurochemical sources of this variability, spinal cord levels of norepinephrine (NE), dopamine (DA), serotonin (5-HT0 and 5-hydroxyindoleacetic acid (5-HIAA) were analysed ipsi- and contralateral to the lesioned side by high performance liquid chromatography at C5-T1 and L1-S1. According to the early or late onset and to the slight or intense autotomy behaviour, the animals were assigned to four different groups: early autotomy, early no autotomy, late autotomy, and late no autotomy. Two sham-operated groups were sacrificed at an early or late stage in the postoperative period. The spinal cord NE content remained unchanged throughout the different experimental situations. The more conspicuous changes observed were: (1) a generalized increase in spinal 5-HT metabolism in all deafferented groups; (2) a significant and selective increase in lumbosacral 5-HT and 5-HIAA levels of the rats that did not self-lesion for 8 weeks after deafferentation and (3) a significant fall (30-45%) in DA levels at denervated spinal segments of the rats that actively self-attacked late in the postoperative period. The data suggests that spinal cord serotonergic and dopaminergic influences play an important role in determining the susceptibility to autotomy (and perhaps chronic pain) after peripheral deafferentation.

Changes in contralateral protein metabolism following unilateral sciatic nerve section

Changes in nerve biochemistry, anatomy, and function following injuries to the contralateral nerve have been repeatedly reported, though their significance is unknown. The most likely mechanisms for their development are either substances carried by axoplasmic flow or electrically transmitted signals. This study analyzes which mechanism underlies the development of a contralateral change in protein metabolism. The incorporation of labelled amino acids (AA) into proteins of both sciatic nerves was assessed by liquid scintillation after an unilateral section. AA were offered locally for 30 min to the distal stump of the sectioned nerves and at homologous levels of the intact contralateral nerves. At various times, from 1 to 24 h, both sciatic nerves were removed and the proteins extracted with trichloroacetic acid (TCA). An increase in incorporation was found in both nerves 14-24 h after section. No difference existed between sectioned and intact nerves, which is consistent with the contralateral effect. Lidocaine, but not colchicine, when applied previously to the nerves midway between the sectioning site and the spinal cord, inhibited the contralateral increase in AA incorporation. It is concluded that electrical signals, crossing through the spinal cord, are responsible for the development of the contralateral effect. Both the nature of the proteins and the significance of the contralateral effect are matters for speculation.

Neuropeptide expression in rat dorsal root ganglion cells and spinal cord after peripheral nerve injury with special reference to galanin

The temporal course of changes in peptide expression in the dorsal root ganglia L4 and L5 and in the dorsal horn of the spinal cord has been studied in rats subjected to a sciatic nerve transection at a mid-thigh level following different survival times. Galanin-, substance P-, vasoactive intestinal polypeptide-, peptide histidine-isoleucine- and calcitonin gene-related peptide-like immunoreactivities have been studied both by immunohistochemistry and radioimmunoassay. Galanin messenger ribonucleic acid has also been studied by in situ hybridization in the dorsal root ganglia of normal and lesioned animals. In addition, a group of animals with a sciatic nerve crush was studied to compare possible differences in peptide expression after both types of lesions. The results show that the transection induces an increase in the number of cell bodies expressing galanin-like immunoreactivity in the ganglia, and that the galanin levels rise about 120-fold after three and 14 days of survival. This increase reflected increased synthesis of the peptide, since there was a rise in the galanin messenger ribonucleic acid already at 24 h post-lesion, which was maintained for at least 60 days. In the spinal cord there was an increase of staining in the midportion of the outer layers of the dorsal horn that corresponded to fibers thought to arise from cells of the dorsal root ganglia affected by the transection. Also a depletion of substance P-like and an increase in vasoactive intestinal polypeptide- and peptide histidine-isoleucine-like immunoreactivities in the dorsal root ganglia were confirmed. These changes were shown to be rapidly detectable and were paralleled by similar changes in the dorsal horn of the spinal cord. For calcitonin gene-related peptide the immunohistochemistry was inconclusive, and the radioimmunoassay showed no detectable changes. After nerve crush a transient increase in the number of galanin immunoreactive neurons was observed, as well as a decrease in the number of neurons showing substance P-like immunoreactivity. These changes were most noticeable between six and 14 days of survival. After this, peptide expression seemed to return slowly to normal, that is by day 45 post-crush only a few cells showed galanin-like, and many sensory neurons expressed substance P-like immunoreactivity. The results demonstrate that when primary sensory neurons are peripherally lesioned they respond in a complex manner, altering their normal production of peptides by increasing or decreasing their synthesis.(ABSTRACT TRUNCATED AT 400 WORDS)

Tubulin messenger RNA: in situ hybridization reveals bilateral increases in hypoglossal and facial nuclei following nerve transection

We have examined the levels of mRNA coding for tubulin in cranial nerve motor nuclei following axotomy using in situ hybridization histochemistry. Following division of their peripheral axons, the neurons in the facial and hypoglossal nuclei show increased levels of tubulin mRNA both ipsilateral and contralateral to the lesion. Tubulin in situ hybridization histochemistry provides a sensitive technique to monitor dynamics of neuronal regrowth or sprouting in the peripheral and possibly the central nervous system.

Changes in neurotransmitter uptake in the spinal cord following peripheral nerve injury

Changes in neurotransmitter systems of the spinal cord were studied in response to peripheral nerve injury. The uptake and compartmentalization of radiolabeled spinal cord neurotransmitters and transmitter precursors were examined as a function of time following unilateral sciatic nerve crush in adult mice. Accumulation of transmitter was measured within synaptosomally enriched fractions prepared using combinations of differential and density gradient centrifugations. The amount of transmitter substance recovered from these fractions was strongly dependent upon the amount of time following nerve injury and on the specific transmitter or precursor being examined (GABA, glutamate, glycine, and choline chloride). However, for each of these substances, uptake values returned to control levels within nine to twelve days after nerve crush. Localization of GABA changes postcrush revealed reciprocal differences between ipsilateral and contralateral sides of the spinal cord, as well as differences between segmental levels. Altered GABA uptake may reflect changes in the postcrush microchemical environment present during tissue processing, but may also be related to direct changes in the synaptic binding, transport, and compartmentalization of transmitter substance. The time course, magnitude, and direction of these neurochemical changes follow those observed neurophysiologically, and may thus underlie injury-induced short-term (days) alterations reported in primary afferent depolarizations, cross cord responses, and other spinal mechanisms.

Protein composition and synthesis in the adult mouse spinal cord

Properties of spinal cord proteins were studied in adult mice subjected to unilateral crush or electrical stimulation of sciatic nerve. The protein composition of spinal tissue was determined using SDS-polyacrylamide gel electrophoresis coupled with subcellular fractionation. Comparisons of mouse spinal cord and brain revealed similarities in the types but differences in the concentrations of myelin associated proteins, nuclear histones and other proteins. Comparisons with sciatic nerve proteins demonstrated differences in types of proteins but similarities in the concentration of myelin proteins and nuclear histones. The short term (less than 2 hrs.) incorporation of radioactive amino acids into spinal cord proteins revealed heterogeneous rates of incorporation. Neither nerve crush six days prior to testing nor sciatic nerve stimulation had a significant effect on the protein composition or amino acid incorporation rates of spinal cord tissue. These observations suggest that known differences in spinal cord function following alterations in nerve input may be dependent upon different mechanisms than have been found in the brain.

Morphometric measurements and RNA content of axotomized feline cervical motoneurons

Microspectrophotometric estimates of RNA content and morphometric measurements of cytoplasmic, nuclear and nucleolar areas were made on 30 to 60 motoneurons (somal areas greater than 1000 microns2) ipsilateral and contralateral to brachial plexotomy performed unilaterally on adult cats 2-90 days before sacrifice. Nerve cells of unoperated animals were also assayed. Somal and cytoplasmic areas of axotomized motoneurons were larger than those of the corresponding, contralateral motor nerve cells 4, 6 and 75 days postoperatively. Because of between animal variability, it could not be determined, however, whether this difference was due to an increase in the area of the axotomized motoneurons or to a decrease in the area of the contralateral nerve cells. Nucleolar sizes did not change. In contrast, nuclei of axotomized motoneurons showed a temporary but unequivocal areal decrease. The cytoplasmic RNA content of axotomized motoneurons fell 14-28 days postoperatively but rose thereafter, being increased slightly but significantly 75-90 days after operation. At no postoperative interval, however, did the nucleolar RNA content of the axotomized cells deviate unequivocally from the unoperated or zero day condition. The following points may be emphasized: 1. these results differ from similar measurements of axotomized motoneurons of rodents and lagomorphs; 2. the data do not provide certain evidence of change in either morphometric parameters or RNA content of motoneurons on the side contralateral to surgery, although the possibility of a decrease in the size of these uninjured neurons should be considered; 3. morphometric and RNA measurements on axotomized peripheral (extrinsic) neurons of spinal anterior horn of cat contrast with similar measurements on axotomized central (intrinsic) neurons of cat red nucleus.