L5 DRG Research Articles

Sensory Impairments and Delayed Regeneration of Sensory Axons in Interleukin-6-Deficient Mice

Interleukin-6 (IL-6) is a multifunctional cytokine mediating inflammatory or immune reactions. Here we investigated the possible role of IL-6 in the intact or lesioned peripheral nervous system using adult IL-6 gene knockout (IL-6(-/-)) mice. Various sensory functions were tested by applying electrophysiological, morphological, biochemical, and behavioral methods. There was a 60% reduction of the compound action potential of the sensory branch of IL-6(-/-) mice as compared with the motor branch in the intact sciatic nerve. Cross sections of L5 DRG of IL-6(-/-) mice showed a shift in the relative size distribution of the neurons. The temperature sensitivity of IL-6(-/-) mice was also significantly reduced. After crush lesion of the sciatic nerve, its functional recovery was delayed in IL-6(-/-) mice as analyzed from a behavioral footprint assay. Measurements of compound action potentials 20 d after crush lesion showed that there was a very low level of recovery of the sensory but not of the motor branch of IL-6(-/-) mice. Similar results of sensory impairments were obtained with mice showing slow Wallerian degeneration (Wlds) and a delayed lesion-induced recruitment of macrophages. However, in contrast to WldS mice, in IL-6(-/-) mice we observed the characteristic lesion-induced invasion of macrophages and the upregulation of low-affinity neurotrophin receptor p75 (p75LNTR) mRNA levels identical to those of IL-6(+/+) mice. Thus, the mechanisms leading to the common sensory deficiencies were different between IL-6(-/-) and WldS mice. Altogether, the results suggest that interleukin-6 is essential to modulate sensory functions in vivo.

The Effect of Site and Type of Nerve Injury on Spinal Glial Activation and Neuropathic Pain Behavior

A number of rat peripheral neuropathy models have been developed to simulate human neuropathic pain conditions. The current study sought to determine the relative importance of site versus type of peripheral nerve injury in eliciting mechanical allodynia and spinal glial responses. Rats received one of seven different surgical treatments at the L5 spinal level: spinal nerve cryoneurolysis, spinal nerve tight ligation, dorsal root cryoneurolysis, dorsal root tight ligation, dorsal root transection, ventral root tight ligation, or laminectomy/dural incision sham. Foot-lift response frequency to mechanical stimulation of the ipsilateral hindpaw was assessed postlesion on days 1, 3, 5, and 7. L5 spinal cords were retrieved for immunohistochemical analysis of microglial (OX-42) and astrocytic (anti-glial fibrillary acidic protein) responses. Both types of spinal nerve lesion, freeze and tight ligation, produced rapid and profound mechanical allodynia with intense glial responses. Dorsal root lesions also resulted in intense mechanical allodynia; however, glial responses were almost exclusively astrocytic. Ventral root tight ligation and sham provoked no marked behavioral changes and only sporadic glial responses. Direct dorsal horn communication with the dorsal root ganglion was not a crucial factor in the development of mechanical allodynia, since decentralization of the L5 DRG by complete L5 dorsal root lesion produced profound mechanical sensitization. Conversely, microglial activation responses appear to be dependent upon dorsal root ganglion-mediated signals and, contrary to behavioral responses, were robust only when the lesion was made peripheral to the cell body. Astrocytic activation was always observed following axonal injury and reliably coexisted with behavioral responses.

Differential Regulation of Calcitonin Gene-related Peptide (CGRP) in Regenerating Rat Facial Nucleus and Dorsal Root Ganglion.

The content of calcitonin gene-related peptide (CGRP) and CGRP-mRNA were determined in axotomized rat facial motor nucleus and sensory fifth lumbar dorsal root ganglion (L5 DRG) using radioimmunoassay and Northern blot analysis. After facial nerve transection CGRP levels in the facial nucleus showed a biphasic, approximately five-fold increase. A first peak occurred at postoperative day 3 and, after a transient decrease to normal levels at day 9, another increase was observed reaching a peak around the time of reinnervation (postoperative day 21). CGRP-mRNA showed a similar, biphasic increase. The first peak in CGRP mRNA preceded the peptide peak by 2 days, the second peak was approximately day 21. In contrast, a decrease in CGRP levels is seen in L5 DRG after sciatic nerve section, reaching minimal levels of 45% of control during the second postoperative week. CGRP-mRNA in axotomized DRG also decreases preceding the decrease in peptide levels. No recovery to normal levels is seen for either peptide or mRNA levels in regenerating DRG up to 45 days after injury. Thus, axotomy leads to a differential regulation of both CGRP and CGRP-mRNA in regenerating facial motor nucleus and sensory L5 DRG. This difference may be due to different regulating factors present in both the respective target tissues and the CNS regions and could reflect different functions of CGRP in regenerating motor and sensory neurons.