Protein S-nitrosylation and denitrosylation in the mouse spinal cord upon injury of the sciatic nerve

Nitric oxide is a pain signaling molecule and exerts its influence through two primary pathways: by stimulation of soluble guanylylcyclase and by direct S-nitrosylation (SNO) of target proteins. We assessed in the spinal cord the SNO-proteome with two methods, two-dimensional S-nitrosothiol difference gel electrophoresis (2D SNO-DIGE) and SNO-site identification (SNOSID) at baseline and 24h after sciatic nerve injury with/without pretreatment with the nitric oxide synthase inhibitor L-NG-nitroarginine methyl ester (L-NAME). After nerve injury, SNO-DIGE revealed 30 proteins with increased and 23 proteins with decreased S-nitrosylation. SNO-sites were identified for 17 proteins. After sham surgery only 3 proteins were up-nitrosylated. L-NAME pretreatment substantially reduced both constitutive and nerve injury evoked up-S-nitrosylation. For the top candidates S-nitrosylation was confirmed with the biotin switch technique and time course analyses at 1 and 7days showed that SNO modifications of protein disulfide isomerase, glutathione synthase and peroxiredoxin-6 had returned to baseline within 7days whereas S-nitrosylation of mitochondrial aconitase 2 was further increased. The identified SNO modified proteins are involved in mitochondrial function, protein folding and transport, synaptic signaling and redox control. The data show that nitric oxide mediated S-nitrosylation contributes to the nerve injury-evoked pathology in nociceptive signaling pathways.     

Excitability changes in the sciatic nerve and triceps surae muscle after spinal cord injury in mice

Background

Ischemia reperfusion (I/R) is common in various pathological conditions like diabetic complication, rheumatic arthritis, necrotizing vascular occlusive disease and trauma.

Methods

We have evaluated the effect of tacrolimus (1, 2 and 3 mg/kg, p.o. for 10 consecutive days) on femoral arterial ischemic reperfusion (I/R) induced neuropathic pain in rats. Behavioral parameters (i.e. hot plate, radiant heat, acetone drop, tail heat hyperalgesia, tail flick and tail cold allodynia tests) were assessed at different time intervals (i.e. 0, 1, 4, 7, 10, 13 and 16^th day) and biochemical analysis in serum and tissue samples were also performed along with histopathological studies.

Results

Behavioral pain assessment revealed increase in the paw and tail withdrawal threshold in tacrolimus treated groups against hyperalgesic and allodynic stimuli as compared to the sham control group. We observed a decrease in the serum nitrate and thiobarbituric acid reactive substance (TBARS) levels along with reduction in tissue myeloperoxidase (MPO) and total calcium levels, whereas, rise in tissue reduced glutathione levels in tacrolimus treated groups. However, significant results were obtained in medium and high dose treated group as compared to sham control group. Histopathological study had revealed the increase in the neuronal edema and axonal degeneration in the I/R group whereas, tacrolimus ameliorate these effects.

Conclusion

Our results indicate the anti-oxidative, anti-inflammatory and calcium modulatory actions of tacrolimus. Therefore, it can be used as a therapeutic agent for the treatment of vascular inflammatory related neuropathic pain.     

In vivo imaging of single axons in the mouse spinal cord

We provide a protocol that describes imaging of single fluorescently labeled axons in the spinal cord of living mice. This method takes advantage of transgenic mouse lines in which the thy1-promoter drives the expression of variants of the green fluorescent protein in a small percentage (less than 1%) of sensory neurons. As a consequence, single axons can be resolved in the surgically exposed dorsal column using wide-field epifluorescence microscopy. This approach allows direct observation of axonal degeneration and regeneration in mouse models of spinal cord pathology for several hours or repetitively over the course of several days.     

Myelinated nerve cell perikaryon in mouse spinal cord

Summary In the thoracic cord (posterior horn region) of a wild mouse, we have observed a small nerve cell soma completely enveloped by a myelin sheath. The number of myelin lamellae varied between 7 and 12. In one place, the existence of an inner mesoperikaryon could also be shown. The significance of this fortuitous finding has not yet been explained.

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Zusammenfassung Im Thorakalmark (Hinterhornbereich) einer Wildmaus wurde ein kleines Nervenzellperikaryon beobachtet, das vollständig von einer Markscheide umhüllt war. Die Zahl der Markscheidenlamellen variierte zwischen 7 und 12. An einer Stelle konnte ein sogenanntes inneres Mesoperikaryon nachgewiesen werden. Die Bedeutung dieses zufällig erhobenen Befundes ist vorerst noch offen.

     

Limb movements generated by stimulating muscle,nerve and spinal cord

We have compared the movements generated by stimulation of muscle, nerve, spinal roots and spinal cord in anesthetized, decerebrate and spinalized cats. Each method produced a full range of movements of the cat's hind limb in the sagittal plane against a spring load, except for stimulation of the roots. Stimulation of the dorsal roots produced movements that were mainly up and forward, whereas stimulation of the ventral roots produced complementary movements (down and backward). Results from stimulation in the intermediate areas of the spinal cord were compared to predictions of the "movement primitives" hypothesis. We could not confirm that the directions were independent of stimulus amplitude or the state of descending inputs. Pros and cons of stimulating at some sites were provisionally considered for the reliable control of limb movements with functional electrical stimulation (FES) in clinical conditions.     

Differential effects of intravitreal optic nerve and sciatic nerve grafts on the survival of retinal ganglion cells and the regeneration of their axons

We have investigated the effects of intravitreal sciatic nerve (SN) and/or optic nerve (ON) grafts on the survival and the axonal regeneration of retinal ganglion cells (RGCs). Following transection of the ON, approximately 40% RGCs survived at 7 days post-axotomy (dpa). Results showed that the intravitreal ON graft significantly promoted the survival of RGCs at 7 dpa (39,063 vs 28,246). Intravitreal SN graft, however, did not rescue axotomized RGCs at 5, 7 or 14 dpa. Axotomized RGCs could be induced to regenerate axons along a segment of SN graft attached to the proximal stump of ON. On average, 608 axotomized RGCs were induced to regenerate axons along the attached SN graft. The presence of intravitreal SN graft promoted about 100% increase in the number of regenerating RGCs (1,227) relative to the control groups. The intravitreal ON graft, surprisingly, also induced about 100% more regenerating RGCs (1220) than in the control group. When SN and ON grafts were co-transplanted into the vitreous, about 200% more regenerating RGCs (1916) were observed than in the control group. These findings illustrated that the intravitreal ON graft rescued axotomized RGCs and enhanced the regeneration of retinal axons. This is the first report to show that ON promotes RGC axonal regeneration. The intravitreal SN graft did not rescue RGCs but promoted axonal regeneration. The differential effects of intravitreal ON and SN grafts on the survival and the RGC regeneration suggest that these might be two independently operating events.     

Vitamin E concentrations in different regions of the spinal cord and sciatic nerve of the rat

Since the spinal cord and peripheral nerves are vulnerable to the effects of vitamin E deficiency, vitamin E concentrations in various discrete regions of these parts of the nervous system of the rat were determined. Furthermore, as acrylamide toxicity and vitamin E deficiency share some neuropathological features, tissue vitamin E concentrations in acrylamide-treated rats were also studied. Male Sprague Dawley rats (200 to 250 g body weight) were fed normal rat chow with or without 0.03% acrylamide in their drinking water. After 24 days, the animals were sacrificed and the tissues assayed for vitamin E by a liquid chromatographic method. Vitamin E concentrations decreased from cerebral cortex to spinal cord with no concentration gradients between different levels of the spinal cord. Sciatic nerve concentration of alpha tocopherol was as high as that of cerebral cortex, and the former also contained measurable amounts of gamma tocopherol. Vitamin E concentrations in the majority of nervous tissue samples remained unchanged with acrylamide treatment.Presented in part at the Sixteenth Annual Meeting of the American Society for Neurochemistry, March 1985.     

Microtubules in myelinated and unmyelinated axons of rat sciatic nerve

Summary Tannic acid in glutaraldehyde was used to stain microtubules in myelinated and unmyelinated axons of rat sciatic nerve. In the majority of areas the tannic acid failed to penetrate the unmyelinated axons whilst penetrating neighbouring myelinated axons, suggesting a difference in the ability of the two types of nerves to exclude tannic acid. Where tannic acid had penetrated the unmyelinated axons the 13 protofilament substructure and size of the microtubules appeared identical to those seen in the myelinated axons.     

Cellular-scale transport in deformed skeletal muscle following spinal cord injury

Deep tissue injury (DTI) is a severe pressure ulcer initiating in weight-bearing skeletal muscles. Being common in spinal cord injury (SCI) patients, DTI is associated with mechanical cell damage and ischaemia. Muscle microanatomy in SCI patients is characterised by reduced myofibre sizes and smaller, fewer capillaries. We hypothesise that these changes influence mass transport in SCI muscles, making DTI more probable. Using multiphysics models of microscopic cross-sections through normal and SCI muscles, we studied effects of the following factors on transport of glucose and myoglobin (potential biomarker for early DTI detection): (i) abnormal SCI muscle microanatomy, (ii) large tissue deformations and (iii) ischaemia. We found that the build-up of concentrations of glucose and myoglobin is slower for SCI muscles, which could be explained by the pathological SCI microanatomy. These findings overall suggest that microanatomical changes in muscles post-SCI play an important role in the vulnerability of the SCI patients to DTI.     

Appearance and phosphorylation of the 210 kDalton neurofilament protein in newborn rat brain,spinal cord,and sciatic nerve

The appearance and in vivo phosphorylation of the 210 kDalton (kD) neurofilament protein (NF210K) in newborn rat brain, spinal cord, and sciatic nerve were invetigated. Electron microscopic examination of neurofilaments isolated from newborn rat brain and spinal cord demonstrated morphologically distinct filaments which contained cross-bridging side arms. Neurofilament proteins, phosphorylated in vivo, were separated by sodium dodecyl sulfate slab gel electrophoresis and were transferred from acrylamide gels to nitrocellulose sheets. The nitrocellulose sheets were treated with antiserum to the 70 kD, 145 kD and 210 kD neurofilament proteins by the immunoblot technique. The three neurofilament proteins were found to be present in newborn brain, spinal cord and sciatic nerve. The presence of NF210K in newborn rat brain was further confirmed by 2-dimensional gel electrophoresis followed by indentification of this protein by the immunoblot technique. Exposure of the immunostained nitrocellulose sheets to x-ray film revealed that the NF210K, NF145K, and NF70K proteins were phosphorylated in filaments prepared from newborn rat central and peripheral nervous systems. These results suggest that the synthesis and posttranslational modification of the neurofilament proteins may be synchronized or developmentally regulated. It is feasible that phosphorylation of the NF210K subunit may be a prerequisite for the formation of neurofilament cross-bridging elements which are necessary for radial growth of axons.     

Effect of axotomy on cholinergic enzyme activities in the spinal cord and sciatic nerve of the dog

Choline acetyltransferase (ChAT) and acetylcholinesterase (AChE) activity measured in the ventral and dorsal part of the dog spinal cord (L6-S2) and in the stumps of the sciatic nerve 5, 10, 15 and 21 days after its transection were compared with the corresponding activities in the intact contralateral nerve and in sham-operated animals. AChE was also examined histochemically. Changes in the enzyme activities in the central nerve stump were correlated with activity changes in the spinal cord. In the central nerve stump, a marked (25%) increase in AChE activity was found on the fifth day after transection, but by the 21st day it fell below control value levels; up to the 15th day it showed good correlation with AChE activity in the ventral spinal cord. Histochemically, pronounced reduction of enzymatic activity was found in the ipsilateral part of the spinal cord. On the 15th day, ChAT activity in the ventral spinal cord was also significantly decreased and the accumulation of the enzyme in the central nerve stump was negligible. On the contrary, at the last 21-day interval examined, a significant increase in ChAT activity and a nonsignificant increase in AChE activity was found in the spinal cord, but their activities in the central nerve stump were decreased. In the degenerated peripheral nerve stump ChAT activity dropped by an average of 99% and AChE activity by 48% during the first 15 days after transection but, on the 21st day, AChE activity was 22% higher than at the preceding interval.