Library

Notes: Abstract: Retrograde axonal transport of phospholipid was studied in rat sciatic motoneuron axons by placing collection crushes on the nerve at intervals after injection of [methyl-3H]choline into the lumbosacral spinal cord, and allowing labelled material undergoing anterograde or retrograde movement to accumulate adjacent to the collection crushes. Control experiments showed that the accumulations of label were not a result of local uptake of circulating precursor. The majority of the 3H label was associated with phosphatidylcholine. Accumulation of label at the distal collection crush, representing retrograde transport, was observed subsequent to the anterograde transport of phospholipid. In comparison with previous study on retrograde transport of protein, the following points were noted: (1) onset of retrograde transport occurred at approximately the same time after precursor injection (10–20 h) for both protein and phospholipid; (2) retrograde transport of lipids was more prolonged: maximum retrograde transport occurred later for phospholipid (30 h) than for protein (15–20 h), and declined to half-maximum between 49 and 99 h, compared to a corresponding value of 24–28 h for protein; (3) the proportion of total anterograde-transported activity subsequently undergoing retrograde transport was less in the case of phospholipid, at least over the time interval studied (up to 99 h after precursor injection). The similar times of onset of retrograde transport of phospholipid and protein support the concept of retrograde transport as a recycling mechanism returning to the cell body membrane fragments that were earlier transported into the axon. Coordinated retrograde transport of labelled protein and phospholipid components of the recycled membranes would be predicted. Differences between protein and phospholipid in the subsequent time course and amount of retrograde transport may reflect differences in axonal handling of protein and lipid. Both the more prolonged outflow of labelled lipids from cell body into axon and exchange with a distal pool of unlabelled phospholipid may account for the prolonged time course of retrograde transport of labelled lipid.

Notes: Abstract: Axonal transport of glycoconjugates was studied in the motoneurons of rat sciatic nerve following injection of [3H]glucosamine into the lumbosacral spinal cord. After varying time intervals, the sciatic nerve was exposed, and two ligatures were tied for collection of materials undergoing anterograde and retrograde transport. Gangliosides and glycoproteins were found to undergo fast anterograde transport, estimated at 284–446 mm/day. Both classes underwent retrograde transport as well, with labeled glycoproteins returning slightly ahead of labeled gangliosides. Only minor quantities of labeled proteoglycans were detected. Purified gangliosides extracted from nerve segments were fractionated according to sialic acid number on diethylaminoethyl-Sephadex; the distributional pattern tended to resemble that of brain gangliosides. The similarity between anterograde and retrograde patterns suggested absence of metabolic changes in gangliosides entering and leaving the axon-nerve terminal structures.

Notes: Complete sciatic nerve injury reduces substance P (SP) expression in primary sensory neurons of the L4 and L5 dorsal root ganglia (DRG), due to loss of target-derived nerve growth factor (NGF). Partial nerve injury spares a proportion of DRG neurons, whose axons lie in the partially degenerating nerve, and are exposed to elevated NGF levels from Schwann and other endoneurial cells involved in Wallerian degeneration. To test the hypothesis that SP is elevated in spared DRG neurons following partial nerve injury, we compared the effects of complete sciatic nerve transection (CSNT) with those of two types of partial injury, partial sciatic nerve transection (PSNT) and chronic constriction injury (CCI). As expected, a CSNT profoundly decreased SP expression at 4 and 14 days postinjury, but after PSNT and CCI the levels of preprotachykinin (PPT) mRNA, assessed by in situ hybridization, and the SP immunoreactivity (SP-IR) of the L4 and L5 DRGs did not decrease, nor did dorsal horn SP-IR decrease. Using retrograde labelling with fluorogold to identify spared DRG neurons, we found that the proportion of these neurons expressing SP-IR 14 days after injury was much higher than in neurons of normal DRGs. Further, the highest levels of SP-IR in individual neurons were detected in ipsilateral L4 and L5 DRG neurons after PSNT and CCI. We conclude that partial sciatic nerve injury elevates SP levels in spared DRG neurons. This phenomenon might be involved in the development of neuropathic pain, which commonly follows partial nerve injury.

Notes: Sympathetic axons invade dorsal root ganglia (DRG) following nerve injury, and activity in the resulting pericellular axonal ‘baskets' may underlie painful sympathetic–sensory coupling. Sympathetic sprouting into the DRG may be stimulated by nerve growth factor (NGF). To test this hypothesis, we investigated the effect of daily anti-NGF administration on pain and on sprouting in the DRG induced by chronic sciatic constriction injury (CCI) or L5 spinal nerve ligation (SNL). These models have been shown to differ subtly in the onset of pain behaviours and adrenergic sprouting, and we now demonstrate a fundamental difference in the way sympathetic axons invade the DRG: after CCI, perivascular noradrenergic collaterals sprouted into the DRG in a manner dependent upon peripherally derived NGF. In contrast, after SNL, regenerating sympathetic axons were diverted towards the DRG from the spinal nerve by the obstructing ligature, and this effect was only moderately impeded by anti-NGF. The differential dependence on anti-NGF suggests that adrenergic innervation of the DRG after SNL and CCI may reflect regenerative and collateral sprouting, respectively. Pain behaviour was similarly affected: anti-NGF completely prevented CCI-induced thermal hyperalgesia and mechanoallodynia, but the same treatment only partly relieved these symptoms following SNL. These differences emphasize that although CCI and SNL may result in similar behavioural abnormalities, the underlying mechanisms may be governed by distinct processes, differentially dependent on peripheral NGF. These mechanistic differences will have to be considered in the development of appropriate treatment strategies for neuropathic pain produced by different types of pathology.

Notes: Abstract Chronic constriction injury (CCI) and partial ligation (PSNL) of the sciatic nerve induce a similar neuropathic pain syndrome in rats. We examined calcitonin gene-related peptide (CGRP), substance P (SP) and protein gene product (PGP) 9.5 immunoreactive (IR) axons in the footpad skin after the two types of injury. Four and 14 days after CCI, CGRP- and SP-IR axons in the ipsilateral footpad skin disappeared in most rats, but in one third, sparse CGRP- and SP-IR fibers remained. PGP-IR axons dramatically decreased, but some thick fiber fascicles appeared. At the ultrastructural level, these PGP-IR thick fiber fascicles were characterized as unmyelinated axons surrounded by non-IR Schwann cells. Some of these axons were swollen and irregular in shape. In contrast, 4 days after PSNL, CGRP-, SP-, and PGP-IR axons in the ipsilateral footpad skin were present, though significantly reduced in density, in all rats, and by 14 days all IR fiber densities in the footpad skin partially recovered. The loss of CGRP and SP axons in the footpad skin of the CCI model suggests that sensory nerves containing neuropeptides are not essential in transducing stimuli applied to the footpad skin into neuropathic pain, but the abnormal PGP-IR unmyelinated axons in thick fiber fascicles might play a role. The partial loss and rapid recovery of IR axons in the footpad skin after PSNL shows that the two injury models, causing similar behaviors, are associated with very different patterns of cutaneous innervation at the time when the pain syndrome is well developed.