Selective responses of myenteric neurons to oxidative stress and diabetic stimuli.

BACKGROUND: Diabetes has a differential effect on different subpopulations of myenteric neurons. Our aim was to investigate an in vitro model to examine the pathways underlying the development of nerve changes in diabetes. METHODS: The proportions of neuronal cell bodies containing vasoactive intestinal polypeptide (VIP), neuronal nitric oxide synthase (nNOS) and calbindin relative to the pan-neuronal marker HuC/D were quantified in wholemount preparations of the myenteric plexus of adult rat ileum using double labeling immunohistochemistry. Preparations were maintained in culture for 24 h in the presence and absence of stimuli mimicking the diabetic environment including oxidative stress, carbonyl stress, high glucose and advanced glycation end products (AGEs). Data were compared with the effect of streptozotocin-induced diabetes in vivo. KEY RESULTS Only oxidative stress in vitro produced the same pattern as observed in diabetes with an increase in VIP-, decrease in nNOS-, and no change in calbindin-positive neurons. Carbonyl stress and high glucose caused an increase in VIP-containing neurons without affecting nNOS expression. In contrast, exposure to AGEs only caused a decrease in nNOS-positive neurons. Calbindin expression was unaffected by any of the stimuli. The effects of the stimuli were prevented by the antioxidant, α-lipoic acid, or the carbonyl scavenger, aminoguanidine. CONCLUSIONS & INFERENCES: The results provide evidence that oxidative stress is the common factor in the development of neuronal changes in diabetes; however, the mechanism by which oxidative stress occurs depends on the individual subpopulation of myenteric neurons examined. The presence of calbindin appears to protect myenteric neurons against harmful stimuli.

Effects of equine grass sickness on sympathetic neurons in prevertebral and paravertebral ganglia.

Acute equine grass sickness (EGS) is a fatal disease of horses that is thought to be due to ingestion of a neurotoxic agent causing extensive damage to autonomic neurons. The aim of this study was to compare the effects of EGS on neurons in two sympathetic ganglia, the paravertebral cranial cervical ganglion (CCG) and the prevertebral coeliac/cranial mesenteric ganglion (CG/CMG). Specimens from horses with EGS and controls were obtained post mortem and processed using single and double immunofluorescence labelling for PGP 9.5 and HuC/HuD (pan-neuronal markers), TUNEL and caspase 3 (markers for apoptosis), vasoactive intestinal polypeptide (VIP) and galanin (markers of the cell body response to injury following axotomy or exposure to sympathetic neurotoxins) and tyrosine hydroxylase (TH, marker for noradrenaline synthesis). In control horses, all neurons contained PGP 9.5 and HuC/HuD. There was a significant loss of PGP 9.5 and HuC/HuD expression in samples from horses with EGS that occurred to a greater extent in the CG/CMG than the CCG. The number of caspase 3-positive neurons increased significantly in both ganglia, but TUNEL staining of sympathetic neurons was only significantly increased in the CG/CMG in EGS. No VIP was observed in any ganglia; however, there was a significant increase in galanin-positive neurons in both ganglia in EGS. In the CCG, there was a significant shift towards increased fluorescence intensity for TH, possibly indicating an initial accumulation of TH within the cell body. In contrast, TH fluorescence intensity was significantly reduced in the CG/CMG in EGS correlating with the greater loss of neurons. These results demonstrate that EGS can induce a cell body response that is similar to the response of sympathetic neurons to a chemical neurotoxin. EGS also causes loss of sympathetic neurons, some of which occurs via apoptosis. Changes were more marked in the CG/CMG than the CCG indicating that the prevertebral ganglia were affected earlier than the paravertebral ganglia in the pathological process and had undergone greater neurodegeneration.

Spontaneous axonal regeneration after optic nerve injury in adult rat.

Optic nerves of adult rats were crushed 2 mm behind the eye to examine the ability of retinal ganglion cells (RGCs) to regenerate their axons. Some animals were treated with the immunophilin ligands FK 506 or GPI 1046 for up to 4 weeks. After 10 days to 16 months, regenerating RGC axons were visualized using anterograde tracing and/or electron microscopy. A small proportion of RGC axons regenerated across the lesion site and grew very slowly along the entire optic nerve. Immunophilin ligands had no obvious effect. The regenerating axons were about 0.2 microm in diameter, and usually in clusters surrounded by astrocyte processes. Thus, some CNS axons can spontaneously regenerate long distances within degenerate white matter and this slow regeneration is not accelerated by immunophilin ligands.