Wallerian degeneration of peripheral nerve

Summary The age-dependent loss of the major peripheral nerve lipids (cholesterol, phospholipid, and total galactolipid) was quantitated over a period of 9 weeks of Wallerian degeneration induced by surgical transection of rabbit sciatic nerves in animals of several ages. Proportionate losses of these lipids were determined by calculating the content of each lipid on a per nerve and on a per gram fresh weight basis remaining after a given period of Wallerian degeneration as a percent of original normal values at several times following surgery. The proportionate loss of each lipid from the distal stump was the most prompt and the most complete in nerves transected at 2 weeks of age, and the least in nerves transected at 20 weeks of age. The prompter clearance of these lipids from younger than older degenerating nerve gives convincing evidence that the suggestion from light-microscopic studies of faster clearance of neural debris in younger than in older animals is correct. A possible relationship between these biochemical findings and the phenomenon of greater functional recovery from peripheral nerve injury in younger than in older subjects is discussed.Supported by an N.I.H. grant (NS-10165)     

An immunohistochemical study of phospholipase A2 in peripheral nerve during Wallerian degeneration.

Antiserum raised against purified Crotalus adamanteus venom phospholipase A2 (PLA2) was used to localise the enzyme in normal and crushed sciatic nerve to determine the effect of nerve trauma on PLA2 distribution in the PNS. The tissue was Bouin's fixed, and stained immunohistochemically using the Vectastain ABC technique. Anti-PLA2 antiserum showed weak reactivity with normal rat myelin, while only 'resident' macrophages stained in normal mouse sciatic nerve. Post-crush, in the mouse, myelin staining was localised close to the crush site, with strong lysosomal staining within both 'resident' and invading haematogenously derived macrophages. In the rat, myelin sheaths stained strongly throughout the nerve very soon after crush, but no macrophages were detected using these antisera. Paranodal myelin and some Schmidt-Lanterman incisures were the first regions of the sheath to show an increase in PLA2 staining post-crush, areas where the first ultrastructural changes occur in myelin after trauma, with staining of compact myelin closely following. Our findings support the idea that PLA2 may be involved in the early process of myelin breakdown seen in Wallerian degeneration.     

Collagenosis in Wallerian degeneration depends on peripheral nerve type

In the mature rat we determined the extent of peripheral nerve collagenosis in response to Wallerian degeneration and examined whether or not nonfibroblastic elements such as Schwann cells were important. Collagen was estimated as the hydroxy-proline content of normal and axotomized nerve fascicles after single or double crush lesions of both myelinated and unmyelinated nerves. Crushed unmyelinated nerve produced two to four times more collagen relative to control nerve than did the sciatic nerve. The nature of the interaction between two successive crushes was different in the two nerves. These results suggest that the degree of collagen fibrillogenesis occurring in Wallerian degeneration is dependent on peripheral nerve type and that the presence of myelin is not necessary for collagen fibrillogenesis.     

Critical signaling pathways during Wallerian degeneration of peripheral nerve

Wallerian degeneration is a critical biological process that occurs in distal nerve stumps after nerve injury. To systematically investigate molecular changes underlying Wallerian degeneration, we used a rat sciatic nerve transection model to examine microarray analysis out-comes and investigate significantly involved Kyoto Enrichment of Genes and Genomes (KEGG) pathways in injured distal nerve stumps at 0, 0.5, 1, 6, 12, and 24 hours, 4 days, 1, 2, 3, and 4 weeks after peripheral nerve injury. Bioinformatic analysis showed that only one KEGG pathway (cytokine-cytokine receptor interaction) was significantly enriched at an early time point (1 hour post-sciatic nerve transection). At later time points, the number of enriched KEGG pathways initially increased and then decreased. Three KEGG pathways were studied in further detail: cytokine-cytokine receptor interaction, neuroactive ligand-receptor interaction, and axon guidance. Moreover, temporal expression patterns of representative differentially expressed genes in these KEGG pathways were validated by real time-polymerase chain reaction. Taken together, the above three signaling pathways are important after sciatic nerve injury, and may increase our understanding of the molecular mechanisms underlying Wallerian degeneration.     

Role of microtubule dynamics in Wallerian degeneration and nerve regeneration after peripheral nerve injury

Wallerian degeneration,the progressive disintegration of distal axons and myelin that occurs after peripheral nerve injury,is essential for creating a permissive microenvironment for nerve regeneration,and involves cytoskeletal reconstruction.However,it is unclear whether microtubule dynamics play a role in this process.To address this,we treated cultured sciatic nerve explants,an in vitro model of Wallerian degeneration,with the microtubule-targeting agents paclitaxel and nocodazole.We found that paclitaxel-induced microtubule stabilization promoted axon and myelin degeneration and Schwann cell dedifferentiation,whereas nocodazole-induced microtubule destabilization inhibited these processes.Evaluation of an in vivo model of peripheral nerve injury showed that treatment with paclitaxel or nocodazole accelerated or attenuated axonal regeneration,as well as functional recovery of nerve conduction and target muscle and motor behavior,respectively.These results suggest that microtubule dynamics participate in peripheral nerve regeneration after injury by affecting Wallerian degeneration.This study was approved by the Animal Care and Use Committee of Southern Medical University,China(approval No.SMUL2015081) on October 15,2015.     

Very early activation of m-calpain in peripheral nerve during Wallerian degeneration

Peripheral nerve injury results in a series of events culminating in degradation of the axonal cytoskeleton (Wallerian degeneration). In the time period between axotomy and cytoskeletal degradation (24-48 h in rodents), there is calcium entry and activation of calpains within the axon. The precise timing of these events during this period is unknown. In the present study, antibodies were generated to three distinct peptide epitopes of m-calpain, and a fusion protein antibody was generated to the intrinsic calpain inhibitor calpastatin. These antibodies were used to measure changes in these proteins in mouse sciatic nerves during Wallerian degeneration. In sciatic nerve homogenates and cultured dorsal root ganglion (DRG) neurites, m-calpain protein was significantly reduced in transected nerves very early after nerve injury, long before axonal degeneration occurred. Levels of m-calpain protein remained low as compared to control nerves for the remainder of the 72-h time course. No changes in calpastatin protein were evident. Systemic treatment of animals with the protease inhibitor leupeptin partially prevented the rapid loss of calpain protein. Removal of calcium in DRG cultures had the same effect. These data indicate that m-calpain protein is lost very early after axonal injury, and likely reflect activation and degradation of this protein long before the cytoskeleton is degraded. Calpain activation may be an early event in a proteolytic cascade that is initiated by axonal injury and culminates with axonal degeneration.     

Perineurial permeability and endoneurial edema during Wallerian degeneration of the frog peripheral nerve

Perineurial permeabilities to [3H]sucrose and [14C]dextran (MW = 70,000), and water content, conduction velocity (CV) and maximum amplitude (MAP) of the compound action potential, were determined in Wallerian degenerated nerves (sciatic or tibial) of the frog and compared with values in the contralateral uncut nerves. Three days after transection of the lumbosacral plexuses, about 2 cm proximal to the sciatic nerve, mean water content of the sciatic nerve was significantly higher than in the contralateral uncut nerve. After 10 days, the degenerating sciatic nerve showed significant increases in the mean perineurial permeabilities to [3H]sucrose and [14C]dextran when compared to values in the contralateral nerve. Means MAP's and CV's were significantly decreased. At 21 days and after, no compound action potential was detected and perineurial permeability and nerve water content had increased further. Decreases in mean MAP's and CV's and permeability increases of the perineurium were less in degenerating tibial nerves than in degenerating sciatic nerves. It is concluded that following transection, (1) Wallerian degeneration produces an irreversible increase in perineurial permeability, (2) the increase of perineurial permeability follows a proximodistal gradient, and (3) the frog peripheral nerve develops endoneurial edema during Wallerian degeneration as do degenerated nerves of mammals.     

On the occurrence of the fenestrated vessels in Wallerian degeneration of the peripheral nerve

Summary Ultrastructural studies were made on the distal segments of the mouse phrenic nerve after crush injury. In the control, endoneurium contained only unfenestrated capillaries. In the experiment, from day 2 to day 6, endoneurial capillaries occasionally showed fenestrations with the attenuation of its cytoplasm. At this stage, axonal degeneration and myelin breakdown became evident showing early stage of Wallerian degeneration. In addition, detachment of the neighboring endothelial cells concomitant with the invasion of macrophage was also observed. These findings were previously unobserved changes of the endoneurial endothelium in Wallerian degeneration. The significance of the early occurrence of fenestrae was discussed briefly.     

Expression of the neu proto-oncogene by Schwann cells during peripheral nerve development and Wallerian degeneration.

The neu gene, which encodes a putative tyrosine kinase growth factor receptor termed p185neu, was originally identified as a dominant transforming gene in neurogliomas and schwannomas induced by transplacental treatment of rat embryos with ethylnitrosourea. The present studies were undertaken to determine the expression pattern of the neu gene in peripheral nerve. Northern blot analysis of total RNA isolated from rat sciatic nerves demonstrated prominent neu mRNA expression on postnatal days 1 and 7, with substantially lower expression up to adulthood. Immunohistochemical studies confirmed expression of p185neu by Schwann cells (SC) in developing sciatic nerve and minimal p185neu immunoreactivity in adult nerves. However, neu mRNA and p185neu protein progressively increased following sciatic nerve transection in adult animals. In addition, neu mRNA and p185neu were found in neonatal rat sciatic nerve SC and several SC-derived cell lines. In resting SC, neu mRNA was expressed at a low level, but was greatly increased by treatment with forskolin and glial growth factor. These studies demonstrate that the neu gene and its protein product, p185neu, are expressed by SC both in vivo and in vitro and suggest that p185neu plays a role in the regulation of SC proliferation or differentiation.     

Wallerian degeneration in the optic nerve of the wabbler-lethal (wl/wl) mouse.

Optic nerve pathology was studied in C57BL/6J wabbler-lethal (wl/wl) and control (+/+) mice at postnatal age of 4 weeks (P28). Qualitative light and ultrastructural pathology in wl/wl animals conformed to the criteria of primary axonal (Wallerian) degeneration. Most optic nerve axons in mutant animals appeared normal, as did oligodendroglia, the degree of myelination, the integrity and maturity of vascular elements, astroglia, and most myelin. Still, degenerating axons surrounded by somewhat normal myelin and axons with thickened myelin sheaths were prevalent in wl/wl mice. Dysmyelination or hypomyelination was not evident. At P28, pathology appeared more prominent in large diameter fibers. In the optic nerve of wl/wl mice, axonal degeneration preceded myelin disruption, adding this nerve to other previously reported systems undergoing Wallerian degeneration in this mutant.     

The spatio-temporal pattern of Wallerian degeneration in mammalian peripheral nerves

Newborn to 9-week kittens were perfused with a paraformaldehyde-glutaraldehyde solution. Thoraco-lumbar segments of the spinal cord were removed and processed for examination with the electron microscope. The results of this study indicate that, at birth, the dendrites of Clarke's nucleus have few if any neurofilaments, microtubules being the prominent component. By 3 weeks, distinctive filament ‘packets’ are visible. These ‘packets’ increase in number and complexity until 9 weeks when the arrangement appears to stabilize. Perikaryal changes are less obvious but primarily involve the maturation of the clusters of filaments and tubules which create islets of the other perikaryal organelles. As a result of these observations, it is suggested that the neurofilaments, which are seen to appear within the dendrites of Clarke's nucleus at a delayed time postnatally, serve a structural function in stabilizing the adult morphology. The microtubules, on the other hand, may contribute to the structural support of these large cells during their early development but, with the appearance of the filament component, are responsible for protein transport and particle translocation.     

Nodal and paranodal structural changes in mouse and rat optic nerve during Wallerian degeneration

Ultrastructural changes in nodal and paranodal regions of myelinated mouse and rat optic nerve fibers were followed between 4 h and 28 days during the course of Wallerian degeneration. In the mouse, axoplasmic changes, including accumulation of organelles and segregation of microtubules, were detectable 4 h after transection, and progressed to a maximum level on day 4, at which time many axons were markedly swollen. Dense axoplasm was seen as early as 16 h and was a common feature of degenerating axoplasm at later times. Paranodal changes, which first appeared as early as 16 h after injury, included detachment of terminal loops of myelin from the axolemma, disconnection of terminal loops from compact myelin lamellae and broadening of terminal loops, or separation of the loops from each other, resulting in paranodal elongation. In freeze-fracture replicas, the E-face of the axolemma showed the normal particle distribution as late as days 3-5. By day 8, however, the nodal particles were patchy and the overall nodal particle density was reduced to approximately half normal. Some normal-looking fibers were present at all stages examined, but their number had declined to about half the total population on day 5 and to less than 10% on day 11. In the rat, the overall sequence of events and time course were comparable to those in the mouse. Thus, the morphological changes found follow approximately the same sequence as that described previously in frog nerves, but progress more rapidly in the mouse and rat.     

Effects of energy deprivation on Wallerian degeneration in isolated segments of rat peripheral nerve

An acceleration in the progression of Wallerian degeneration was demonstrated in isolated segments of rat peripheral nerve following incubation under energy-deprivational conditions. The additions of1mM cyanide, azide or dinitrophenol to Ringer's incubational solutions brought about granular disintegrative axoplasmic changes, varicosity formation and linear fragmentation of the myelinated nerve fibers within 2–4 h of incubation at 37°C. Incubations in Ringer's solutions without glucose or with the addition of1mM iodoacetate led to identical Wallerian-like degenerative changes of myelinated fibers during the 8–12 h incubational interval. In contrast, the myelinated nerve fibers remained well-preserved following 16 h of incubation in glucose-enriched Ringer's solutions. The progressions of degenerative changes under energy-deprivational conditions were calcium-dependent as evidenced by their failure to occur in calcium-free media. Accordingly, it is believed that an influx of calcium ions into axoplasm is a critical event in bringing about accelerated as well as the natural degradative changes within isolated nerve fibers. It would follow that the maintenance of axolemmal integrity, especially the calcium-excluding mechanism(s), is an active process which utilizes energy and is vulnerable to energy-deprivational conditions.     

Hereditary absence of complement C5 in adult mice influences Wallerian degeneration, but not retrograde responses, following injury to peripheral nerve.

We have examined the role of complement component 5 (C5) in peripheral nerve fiber degeneration and regeneration, as well as in glial and neuronal cell responses in the central nervous system (CNS). Adult congenic mice lacking C5 (C5(-)) and the corresponding normal strain (C5(+)) were used. Macrophage recruitment as well as axonal and myelin sheath elimination were delayed from 1 to 21 days postinjury in C5(-) mice compared to the C5(+) group after sciatic nerve crush. Despite this, recovery of motor function was not delayed. In the CNS, microglial cells and astrocytes responded in the same way from 3 to 21 days after sciatic nerve injury in C5(-) and C5(+) mice, and the extent of neuron death following hypoglossal nerve avulsion was the same in both groups. These findings suggest that C5 and/or its derivatives play an important role in initiating the recruitment of macrophages to the injured nerve and, probably indirectly, in early remyelination of regenerating axons, but does not influence the longterm functional restoration or axotomy-induced nerve cell death. C5-derived molecules do not appear to participate in central glial cell responses to peripheral nerve injury. These findings elucidate new aspects on the functional role of the complement system in the peripheral nervous system following peripheral nerve injury.     

Phagocytosis in the rat optic nerve following Wallerian degeneration

Summary Unilateral enucleation of the eye in adult male rats was performed in an attempt to resolve the long-standing controversy as to the nature of the phagocytic cells during Wallerian degeneration in the central nervous system. Previously both resident microglia and circulating monocytes, as well as oligodendrocytes, have all been considered to be the phagocytic cells. In these present experiments macrophages and microglia were studied using lectin histochemistry for Griffonia simplicifolia agglutinin and the monoclonal antibody ED1 at light microscopic level. Oligodendrocytes were demonstrated ultrastructurally using immunohistochemistry with monoclonal antibodies against myelin oligodendrocyte glycoprotein (MOG). Ultrastructural examination of the degeneration optic nerves confirmed longstanding reports of the slow nature of breakdown in the adult central nervous system. During the early periods of breakdown, starting at 1 week and continuing to 1 or 2 months, it was difficult to type, on ultrastructural examination alone, the nature of all the cells undergoing phagocytosis, but many of them resembled microglia/macrophages. Myelin debris cleared very slowly and could still be recognised prominently in the nerve up to 22 months post-enucleation. Lectin and immunochemical examination showed that the early major phagocytic component of phagocytosis was carried out by macrophages, probably both circulating and resident. In addition, however, myelin and axonal debris was taken up or retracted into oligodendrocyte processes, which were stained with antibodies to MOG. This oligodendrocyte component appeared to be small in relationship to the overall degree of debris. Phagocytosis in the optic nerve, therefore, is in many respects similar to that in the peripheral nervous system, which has been shown to be carried out mainly by circulating macrophages, with only a minor role played by the Schwann cell.Supported by a grant MA 5818 from the Medical Research Council of Canada     

The spatio-temporal pattern of Wallerian degeneration in the Rhesus monkey optic nerve

Summary Three patterns of degeneration were distinguished in the Rhesus monkey optic nerve following eye enucleation. (1) A traumatic zone, extending for 1 to 2 mm from the site of transection and characterized by a rapid infiltration of haematogenous macrophages, the rapid degeneration and removal of all neural elements and the formation of astrocytic scar tissue within 35 days. (2) A conical zone, closely associated with the central retinal blood vessels, in which the pattern of degeneration was similar to the traumatic zone except that the onset was delayed and the removal of debris was slower. There was extensive vesiculation of myelin sheaths in these two zones which was indicative of haematogenous cell infiltration. (3) The remainder of the nerve underwent classical Wallerian degeneration in which endogenous cells slowly phagocytosed the degenerating nerve fibres. These observations are considered relevant to the controversy concerning the identification of the macrophage involved in Wallerian degeneration; many studies have described the macrophage within the area of trauma rather than the macrophage involved at some distance from the site of trauma.Supported by Grants 692-B-2 from the National Multiple Sclerosis Society; NS 02255 and NS 08180 from the National Institutes of Health and a grant from the Alfred P. Sloan Foundation