Increased calpain content and progressive degradation of neurofilament protein in spinal cord injury

Spinal cord injury was induced in rat by weight drop. The extent of degradation of neurofilament proteins in the lesion following trauma was examined and served as a measure of calpain activity. Calpain was identified in the samples by myelin mealpain antibody and the content was estimated from the immunoblot. There was progressive degradation of both 68 kDa and 200 kDa neurofilament proteins in the cord lesion at intervals after injury. At 30 min after injury there was 20% degradation of both neurofilament proteins while the breakdown of 68 kDa and 200 kDa NFRs amounted to more than 60% at 24 h and beyond. Calpain content progressively increased in the lesion by 22% at 30 min to 91% at 4 h after trauma compared to control and then decreased but remained elevated for up to 72 h following injury. These results suggest that calpain is a primary responder synthesized early in injury and involved initially in the breakdown of cytoskeletal proteins in spinal cord trauma. Later in the injury cascade, increased calpain activity is derived from inflammatory as well as endogenous cells supporting a pivotal role for calpain throughout the process of secondary and evolving tissue damage in spinal cord trauma.     

Cytoskeletal disruption following contusion injury to the rat spinal cord

Following experimental spinal cord injury (SCI), there is a delayed loss of neurofilament proteins but relatively little is known regarding the status of other cytoskeletal elements. The purpose of the present study was to compare the extent and time course of the MAP2 loss with that of neurofilament proteins, and to examine tau protein levels and distribution following SCI. Within 1 to 6 hours following SCI, there is rapid loss of MAP2, tau, and nonphosphorylated neurofilament proteins at the injury site. In contrast, the loss of phosphorylated neurofilament proteins was not significant until 1 week postinjury. In addition to the loss of MAP2 protein, there was extensive beading of MAP2-immunoreactive dendrites extending into the white matter. This was most pronounced 1 hour after injury and gradually resolved such that beading was no longer evident 2 weeks after SCI. The time course of beading resolution is similar to that of behavioral recovery following SCI, but the functional significance of the beading remains to be determined. Together, these results demonstrate that there are 2 phases of cytoskeletal disruption following SCI; a rapid loss of MAP2, tau, and nonphosphorylated neurofilament proteins, and a delayed loss of phosphorylated neurofilaments.     

Cytoskeletal protein degradation and neurodegeneration evolves differently in males and females following experimental head injury

The resulting neuropathological degeneration that occurs following a traumatic brain injury (TBI) is a consequence of both immediate and secondary neurochemical sequelae. Proteolysis of cytoskeletal proteins, triggered by calcium-mediated events, is believed to be a particularly significant contributor to TBI-induced neuronal death. To date, efforts to associate cytoskeletal degradation and neurodegeneration in TBI have been primarily qualitative or semiquantitative. The objectives of this study were (1). to quantitatively describe, over a posttraumatic time course, the relationship and mechanisms of cytoskeletal degradation (Western blot) and neurodegeneration (silver staining) in male and female mice following a moderately severe weight-drop impact-acceleration head injury; (2). to evaluate gender differences in the response to TBI; and (3). to examine the potential therapeutic window for future pharmacological treatment strategies. In male and female mice, we report a close correlation in the time courses of neurofilament M protein degradation and alpha-spectrin breakdown products (SBDP 150 and 145) with the peak magnitude of neurodegeneration, as quantified by silver staining. Evidence from the increased patterns of SBDPs suggests that both calpain and caspase-3 are involved. In general, males incurred peak protein degradation and neurodegeneration within 3 days after injury, while in females this did not occur until 14 days. The neuroprotective effects of estrogen are believed to be key factors in the superior outcome of female vs male mice following TBI. In mice, the therapeutic window of opportunity for pharmacological intervention aimed at limiting cytoskeletal degradation might be as much as 24 h following injury. Evidence of a protracted time course of cytoskeletal degradation, especially in females, suggests a potential for an extended treatment-duration following TBI.     

Rapid loss and partial recovery of neurofilament immunostaining following focal brain injury in mice

Neurofilaments (NF), the intermediate filaments of the neuronal cytoskeleton, provide mechanical stability to the cell. High-molecular-weight NF (NFH) comprises a heavily phosphorylated carboxyl terminal ("sidearm") domain which helps determine interfilament spacing distances. Experimental evidence suggests that dephosphorylation greatly increases the rate and extent of proteolysis of NFH. Because NF proteolysis has been implicated as one pathogenic mechanism underlying cell death following traumatic brain injury (TBI), we analyzed the patterns of acute NFH damage in relation to phosphorylation state following focal, concussive, controlled cortical impact (CCI) brain injury in mice. Brains from C57BL/6 male mice (n = 4 injured and n = 1 sham per time point) were evaluated 5 min, 15 min, 90 min, 4 h, and 24 h following CCI injury (1 mm depth, 5 m/s). Immunohistochemistry was performed using antibodies that recognize epitopes on either dephosphorylated (d-NFH) or phosphorylated (p-NFH) sidearms or on the core (c-NFH) domain. As early as 5-15 min postinjury, immunoreactivity for d-, p-, and c-NFH decreased in the ipsilateral cortex, and hippocampal CA3, CA1, and dentate areas. This marked decrease of NFH labeling occurred in the absence of notable cell loss. Furthermore, partial recovery of NFH labeling was observed as early as 90 min postinjury in the cortex and by 24 h postinjury in hippocampal CA3 and dentate. The results of this study suggest that both phosphorylated and dephosphorylated NFH are vulnerable almost immediately following focal brain injury in mice, but that injured neurons may have an adaptive capability to partially restore this important cytoskeletal protein.     

Neurofilament-rich intraneuronal inclusions exacerbate neurodegenerative sequelae of brain trauma in NFH/LacZ transgenic mice

Several neurodegenerative disorders are characterized by filamentous inclusions in neurons that selectively degenerate. The role these inclusions play in neuron degeneration is unclear, but this issue can be investigated experimentally in relevant animal models. The NFH/LacZ transgenic (TG) mice overexpress the high-molecular-weight neurofilament (NF) subunit (NFH) fused to beta-galactosidase, and these hybrid proteins aggregate into NF-rich, filamentous neuronal cytoplasmic inclusions (NCIs) that have been implicated in the progressive, age-dependent degeneration in subsets of affected neurons. Thus, these TG mice recapitulate some of the key pathology of neurodegenerative disorders with intraneuronal inclusions. To determine if the NCIs compromise neuron survival following traumatic brain injury (TBI), 3- to 6-month old TG and wild-type (WT) mice were subjected to TBI or sham injury. At 2 weeks post-TBI, the TG group showed increased TUNEL staining and activated caspase-3 immunoreactivity in cells of cerebral cortex, adjacent white matter, and hippocampus underlying the injury site, relative to control mice, but this labeling decreased at 4 weeks and was minimal thereafter. Compared to control mice, by 8 weeks postinjury, the TG mice showed a marked decrease in neuron density and increased gliosis in the hippocampal dentate gyrus and CA3 region as well as in the lateral thalamus, while the few remaining CA3 neurons exhibited cytoskeletal alterations, decreased synaptic protein immunoreactivity, and dissolution of NCIs. The more profound long-term neurodegenerative sequelae of TBI in the NFH/LacZ mice compared to WT mice suggest that the presence of intraneuronal inclusions may impair the recovery and long-term viability of injured neurons.     

Moderate posttraumatic hypothermia decreases early calpain-mediated proteolysis and concomitant cytoskeletal compromise in traumatic axonal injury.

Traumatic brain injury (TBI) in animals and man generates widespread axonal injury characterized by focal axolemmal permeability changes, induction of calpain-mediated proteolysis, and neurofilament side-arm modification associated with neurofilament compaction (NFC) evolving to axonal disconnection. Recent observations have suggested that moderate hypothermia is neuroprotective in several models of TBI. Nevertheless, the pathway by which hypothermia prevents traumatic axonal injury (TAI) is still a matter of debate. The present study was conducted to evaluate the effects of moderate, early posttraumatic hypothermia on calpain-mediated spectrin proteolysis (CMSP), implicated in the pathogenesis of TAI. Using moderate (32 degrees C) hypothermia of 90 min duration without rewarming, the density of CMSP immunoreactive/damaged axons was quantified via LM analysis in vulnerable brain stem fiber tracts of hypothermic and normothermic rats subjected to impact acceleration TBI (90 min postinjury survival). To assess the influence of posthypothermic rewarming, a second group of animals was subjected to 90 min of hypothermia followed by 90 min of rewarming to normothermic levels when CMSP was analyzed to detect if any purported CMSP prevention persisted (180 min postinjury survival). Additionally, to determine if this protection translated into comparable cytoskeletal protection in the same foci showing decreased CMSP, antibodies targeting altered/compacted NF subunits were also employed. Moderate hypothermia applied in the acute postinjury period drastically reduced the number of damaged axons displaying CMSP at both time points and significantly reduced NFC immunoreactivity at 180 min postinjury. These results suggest that the neuroprotective effects of hypothermia in TBI are associated with the inhibition of axonal/cytoskeletal damage.     

Gliovascular changes precede white matter damage and long‐term disorders in juvenile mild closed head injury

Traumatic brain injury (TBI) is a leading cause of hospital visits in pediatric patients and often leads to long‐term disorders even in cases of mild severity. White matter (WM) alterations are commonly observed in patients months or years after the injury assessed by magnetic resonance imaging (MRI), but little is known about WM pathophysiology early after mild pediatric TBI. To evaluate the status of the gliovascular unit in this context, mild TBI was induced in postnatal‐day 17 mice using a closed head injury model with two grades of severity (G1, G2). G2 resulted in significant WM edema (increased T2‐signal) and BBB damage (IgG‐extravasation immunostaining) whereas decreased T2 and the increased levels of astrocytic water‐channel AQP4 were observed in G1 mice 1 day post‐injury. Both severities induced astrogliosis (GFAP immunolabeling). No changes in myelin and neurofilament were detected at this acute time point. One month after injury G2 mice exhibited diffusion tensor imaging MRI alterations (decreased fractional anisotropy) accompanied by decreased neurofilament staining in the WM. Both severities induced behavioral impairments at this time point. In conclusion, long‐term deficits and WM changes similar to those found after clinical TBI are preceded by distinct early gliovascular phenotype alterations after juvenile mild TBI, revealing AQP4 as a potential candidate for severity‐based treatments.     

Differentiation of NTERA-2 clonal human embryonal carcinoma cells into neurons involves the induction of all three neurofilament proteins

Monoclonal antibodies were used in indirect immunofluorescence and immunoblot studies to examine the expression of four different classes of intermediate filaments, namely, neurofilaments, glial filaments, cytokeratin, and vimentin, in NTERA-2 cl.D1 (NT2/D1) pluripotent human embryonal carcinoma (EC) cells, and in the neurons derived from these cells by differentiation induced with retinoic acid. In the EC cell cultures, grown in the absence of retinoic acid, cytokeratin was the predominant intermediate filament detected by immunofluorescence; only a few cells expressed vimentin, and none expressed glial filament protein or any of the three neurofilament proteins (NF195, NF170, and NF70). Immunoblot analyses of cytoskeletal extracts of these cells supported these data. Two days after exposure to retinoic acid, all three neurofilament subunits were detected in a few cells with a non-neuronal morphology and, by double indirect immunofluorescence, were observed to colocalize with cytokeratin. The number of neurofilament-positive cells increased with time after initial exposure to retinoic acid, and although 95% of these cells contained cytokeratin initially, less than 5% of the neurofilament-positive cells retained cytokeratin 2 weeks later. By this time, many of the cells expressing all three neurofilaments but no cytokeratin exhibited a neuronal morphology. Vimentin was evident in a large number of cells in the cultures, but it was not detected in the neurofilament-positive cells. Also, many of the neurofilament-negative cells continued to express cytokeratin. No cells expressing glial filament proteins were found. Immunoblot analysis of the differentiated cultures also revealed all three neurofilament subunits, and vimentin and cytokeratin, but no glial filament protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

NEOSTRIATAL CYTOSKELETON CHANGES FOLLOWING PERINATAL ASPHYXIA: EFFECT OF HYPOTHERMIA TREATMENT

Long-term changes of different types of neurofilaments (NF) and glial fibrilar acid protein (GFAP) were studied in neostriatal rat subjected to perinatal asphyxia (PA) under normothermic and hypothermic (15°C) conditions, using immunohistochemistry for light and electron microscopy. Neostriatal neurons of 6-month-old rats that were subjected to 19 and 20 min of PA, showed an increase of NF 200 kDa immunostaining mainly in the axon fascicles in comparison with the control and hypothermia groups. In contrast, no alterations were seen with NF68 and NF160 neurofilament antibodies. Furthermore, the same PA groups showed astroglial cells with enhanced GFAP immunoreactivity, evidencing a typical astroglial reaction with a clear hypertrophy of these cells. A quantitative image analysis confirmed these observations. Hypothermic treated animals did show neither astroglial nor neuronal cytoskeletal changes in comparison to the control group. These findings showed that PA produces chronic cytoskeletal alterations in the neostriatum cells that can be prevented by hypothermia.     

大鼠弥漫性轴突损伤后神经丝68蛋白水平减少

目的：通过检测大鼠弥漫性轴突损伤（DAI）后神经丝蛋白68（NF68）水平，探讨弥漫性轴突损伤的病理机制。方法：用一种对大鼠头颅旋转装置致伤引发大鼠DAI。Sprague-Dawley（SD）大鼠18只随机分成3组（30min,24,72h组），每组6只，在不同时间点取脑白质、海马、胼胝体和脑干标本进行NF68印记杂交（Western blot)，检查神经丝蛋白68 水平。结果：Western blot看到对照动物NF68水平没有变化，而损伤动物明显NF68的丢失，特别是脑干。NF68是蛋白质水平减少在损伤后30min即出现直到损伤后72h。在NF68丢失的同时伴有31、42．7和52Kda低分子量蛋白条带的出现，在24h最明显。结论：NF68降解是由病理性钙蛋白酶激活引起的。损伤后24h内是最佳治疗时机。     

Posttraumatic administration of pituitary adenylate cyclase activating polypeptide in central fluid percussion injury in rats

Several in vitro and in vivo experiments have demonstrated the neuroprotective effects of pituitary adenylate cyclase activating polypeptide (PACAP) in focal cerebral ischemia, Parkinson's disease and traumatic brain injury (TBI). The aim of the present study was to analyze the effect of PACAP administration on diffuse axonal injury (DAI), an important contributor to morbidity and mortality associated with TBI, in a central fluid percussion (CFP) model of TBI. Rats were subjected to moderate (2 Atm) CFP injury. Thirty min after injury, 100 microg PACAP was administered intracerebroventricularly. DAI was assessed by immunohistochemical detection of beta-amyloid precursor protein, indicating impaired axoplasmic transport, and RMO-14 antibody, representing foci of cytoskeletal alterations (neurofilament compaction), both considered classical markers of axonal damage. Analysis of damaged, immunoreactive axonal profiles revealed significant axonal protection in the PACAP-treated versus vehicle-treated animals in the corticospinal tract, as far as traumatically induced disturbance of axoplasmic transport and cytoskeletal alteration were considered. Similarly to our former observations in an impact acceleration model of diffuse TBI, the present study demonstrated that PACAP also inhibits DAI in the CFP injury model. The finding indicates that PACAP and derivates can be considered potential candidates for further experimental studies, or purportedly for clinical trials in the therapy of TBI.     

Activation of Rho after traumatic brain injury and seizure in rats

Traumatic brain injury (TBI) is characterized by a progressive cell loss and a lack of axonal regeneration. In the central nervous system (CNS), the Rho signaling pathway regulates the neuronal response to growth inhibitory proteins and regeneration of damaged axons, and Rho activation is also correlated with an increased susceptibility to apoptosis. To evaluate whether traumatic brain injury (TBI) results in changes in Rho activation in vulnerable regions of the brain, GTP-RhoA pull down assays were performed on rat cortical and hippocampal tissue homogenates obtained from 24 h to 3 days following lateral fluid percussion brain injury (FPI). Following FPI, a significantly increased RhoA activation was observed from 24 h to 3 days post-injury in the cortex and by 3 days in the hippocampus ipsilateral to the injury. We also detected activated RhoA in the cortex and hippocampus contralateral to the injury, without concomitant changes in total RhoA levels. To determine if immediate post-traumatic events such as seizures may activate Rho, we examined RhoA activation in the brains of rats with kainic acid-induced seizures. Severe seizures resulted in bilateral RhoA activation in the cortex and hippocampus. Together, these results indicate that RhoA is activated in vulnerable brain regions following traumatic and epileptic insults to the CNS.     

Neostriatal cytoskeleton changes following perinatal asphyxia: effect of hypothermia treatment

Long-term changes of different types of neurofilaments (NF) and glial fibrillar acid protein (GFAP) were studied in neostriatal rat subjected to perinatal asphyxia (PA) under normothermic and hypothermic (15 degrees C) conditions, using immunohistochemistry for light and electron microscopy. Neostriatal neurons of 6-month-old rats that were subjected to 19 and 20 min of PA, showed an increase of NF 200 kDa immunostaining mainly in the axon fascicles in comparison with the control and hypothermia groups. In contrast, no alterations were seen with NF68 and NF160 neurofilament antibodies. Furthermore, the same PA groups showed astroglial cells with enhanced GFAP immunoreactivity, evidencing a typical astroglial reaction with a clear hypertrophy of these cells. A quantitative image analysis confirmed these observations. Hypothermic treated animals did show neither astroglial nor neuronal cytoskeletal changes in comparison to the control group. These findings showed that PA produces chronic cytoskeletal alterations in the neostriatum cells that can be prevented by hypothermia.     

Glutamate induces rapid loss of axonal neurofilament proteins from cortical neurons in vitro

One of the primary hallmarks of glutamate excitotoxicity is degradation of the neuronal cytoskeleton. Using a tissue culture approach, we have investigated the relationship between excitotoxicity and cytoskeletal degradation within axons, with particular reference to the axon specific neurofilament proteins. Neurofilaments were rapidly lost from axons over a 24-h period in response to excitotoxic insult (as observed by immunocytochemistry and western blotting), while other axonal cytoskeletal markers (such as betaIII-tubulin) remained intact. Treatment with kainic acid and NMDA, or complementary experiments using the pharmacological glutamate receptors blockers CNQX (kainate/AMPA receptor antagonist) and MK-801 (NMDA receptor antagonist), demonstrated that neurofilament degeneration was mediated primarily by NMDA receptor activity. This work suggests that excitotoxicity triggers a progressive pathway of cytoskeletal degeneration within axons, initially characterised by the loss of neurofilament proteins.     

Early loss of the glutamate transporter splice-variant GLT-1v in rat cerebral cortex following lateral fluid-percussion injury

Glutamate transporter proteins are essential for the control of interstitial glutamate levels, with an impairment of their function or levels being a major potential contributor to excitotoxicity. We have investigated the effects of lateral fluid percussion on the levels of the glutamate transporter proteins GLT-1alpha, its splice variant GLT-1v, GLAST, and EAAC1 in the rat in order to evaluate their pathogenetic role in this model of traumatic brain injury (TBI). Immunoblot analysis revealed neuronal loss in the cerebral cortex was accompanied by a 54% decrease in GLT-1v 6 h following the insult which progressed to an 83% loss of the transporter after 24 h. No changes in GLT-1alpha, GLAST, or EAAC1 were observed in this brain region at either time point. GLT-1v content was also decreased by 55% and 68% in the hippocampus and thalamus, respectively, at 6 h post-injury, but recovered fully after 24 h in both brain regions. In contrast, levels of GLT-1alpha were increased in the hippocampus at 6 h and 24 h post-TBI. These alterations in transporter protein content were also confirmed using immunohistochemical methods. Our results show for the first time a pattern of early, dynamic changes in the levels of GLT-1 transporter splice variants in different brain regions in this trauma model. In addition, correlation of GLT-1v levels with both neuronal cell loss and alpha-internexin content in the injured cortex suggests that loss of this novel glutamate transporter may be a key factor in determining cerebral vulnerability following this type of brain injury.     

Evolution of neurofilament subtype accumulation in axons following diffuse brain injury in the pig.

Although accumulation of neurofilament (NF) proteins in axons has been recognized as a prominent feature of brain trauma, the temporal course of the accumulation of specific NF subtypes has not been well established. In the present study, 17 miniature swine were subjected to nonimpact inertial brain injury. At 3 hours (h), 6 h, 24 h, 3 days, 7 days, and 10 days post-trauma, immunohistochemical analysis was performed to determine axonal accumulation of NF-light (NF-L), the rod and sidearm domains and sidearm phosphorylation states of NF-medium (NF-M), and heavy (NF-H). We found that NF-L accumulation was easily identified in damaged axons by 6 h post-trauma, but NF-M and H accumulation was not clearly visualized until 3 days following injury. In addition, the axonal accumulation of NF-M and H appeared to be primarily comprised of the sidearm domains. While the accumulating NF was found to be predominantly dephosphorylated, we also detected accumulation of phosphorylated NF. Finally, we found that developing axonal pathology may proceed either towards axotomy with discrete terminal bulb formation or towards the development of varicose swellings encompassing long portions of axons. These findings suggest that there is a differential temporal course in NF subtype disassembly, dephosphorylation, and accumulation in axons following initial brain trauma and that these processes occur in morphologically distinct phenotypes of maturing axonal pathology.     

Neurofilament proteins and the mesolimbic dopamine system: common regulation by chronic morphine and chronic cocaine in the rat ventral tegmental area.

The ventral tegmental area (VTA) and its dopaminergic projections appear to mediate some of the rewarding properties of opiates, cocaine, and other drugs of abuse. In a previous study, we demonstrated that chronic morphine and cocaine exert common actions on tyrosine hydroxylase, the rate-limiting enzyme in catecholamine biosynthesis, in this dopaminergic brain reward region (Beitner-Johnson and Nestler, 1991). In the present study, we investigated the effects of chronic morphine and cocaine on other phosphoproteins in the VTA by back phosphorylation and two-dimensional electrophoretic analysis. It was found that a number of phosphoproteins, in addition to tyrosine hydroxylase, were regulated similarly by the two drug treatments in this brain region. Several of these morphine- and cocaine-regulated phosphoproteins were identified as neurofilament (NF) proteins. Chronic, but not acute, administration of either morphine or cocaine was found to decrease levels of the three NF proteins, NF-200 (NF-H), NF-160 (NF-M), and NF-68 (NF-L), by between 15% and 50% in the VTA by back phosphorylation, immunolabeling, and Coomassie blue staining. Such regulation of NF proteins was selective, in that no detectable changes were observed in the levels of eight other major cytoskeletal or cytoskeletal-associated proteins analyzed. Furthermore, NF levels were not altered by chronic treatment with either imipramine or haloperidol, two psychotropic drugs without reinforcing properties, or by chronic stress. Morphine and cocaine regulation of NFs showed regional specificity, as NF levels were not altered in the substantia nigra, or other parts of the brain or spinal cord, by these drug treatments. NFs are thought to function as determinants of neuronal morphology and to be associated with axonal transport. Thus, decreased NF levels in the VTA in response to chronic morphine and chronic cocaine could lead to drug-induced alterations in the structural and functional properties of this brain region, which may represent, in turn, part of a common biochemical basis of morphine and cocaine addiction and craving.     

Protein accumulation in traumatic brain injury

Traumatic brain injury (TBI) is one of the most devastating diseases in our society, accounting for a high percentage of mortality and disability. A major consequence of TBI is the rapid and long-term accumulation of proteins. This process largely reflects the interruption of axonal transport as a result of extensive axonal injury. Although many proteins are found accumulating after TBI, three have received particular attention; β-amyloid precursor protein and its proteolytic products, amyloid-β (Aβ) peptides, neurofilament proteins, and synuclein proteins. Massive coaccumulations of all of these proteins are found in damaged axons throughout the white matter after TBI. Additionally, these proteins form aggregates in other neuronal compartments and in brain parenchyma after brain trauma. Interestingly, TBI is also an epigenetic risk factor for developing neurodegenerative disorders, such as Alzheimer’s disease and Parkinson’s disease. Here, the similarities and differences of these accumulations with pathologies of neurodegenerative diseases will be explored. In addition, the potential deleterious roles of protein accumulations on functional outcome and progressive neurodegeneration following TBI will be examined.     

Heavy neurofilament accumulation and alpha-spectrin degradation accompany cerebellar white matter functional deficits following forebrain fluid percussion injury

Evidence for diffuse traumatic axonal injury (TAI) in clinical cases and animal models of traumatic brain injury (TBI) indicate that pathophysiological mechanisms extend to regions remote from the injury epicenter. The potential for indirect cerebellar trauma contributing to TBI pathophysiology is of significance since impairment of motor function and coordination is a common consequence of TBI but is also a domain associated with cerebellar function. The relationship between cerebellar white matter structure and function following traumatic head injury has not been examined. Using the fluid percussion injury (FPI) device applied unilaterally in the forebrain, evoked compound action potential (CAP) recordings from cerebellar white matter of Sprague-Dawley rats indicated a spatial and temporal pattern of electrophysiological deficits throughout the cerebellar vermis. The posterior and middle lobules of the cerebellum exhibited significant declines in evoked CAP amplitude compared to sham controls (p=0.004, p=0.005, respectively). Duration of the CAP decay also increased, suggesting that functional white matter deficits were a combination of axonal loss and compromised axonal integrity. Functional white matter deficits persisted at 14 days post-injury in the posterior and middle regions of the cerebellum. Evidence of heavy chain neurofilament (NF200) degradation was observed at 1 day post-injury by Western blot. Immunohistochemistry labeling for NF200 indicated the presence of highly immunoreactive NF200 axonal swellings consistent with morphological features of TAI. alpha-Spectrin degradation was also observed between 1 and 14 days post-injury. This study demonstrates the electrophysiological consequences of cerebellar white matter injury and a temporal profile of NF200 and spectrin degradation following forebrain FPI.     

Novel monoclonal antibodies provide evidence for the in situ existence of a nonphosphorylated form of the largest neurofilament subunit

We have obtained five monoclonal antibodies to the Mr 200,000 neurofilament component (NF200) after immunization with polypeptides purified from enzymatically dephosphorylated bovine neurofilaments. In immunoblots of untreated neurofilament protein and protein from filaments exposed to phosphatase, these antibodies recognize nonphosphorylated or dephosphorylated, but not phosphorylated, forms of NF200. The epitopes recognized by these new monoclonal antibodies reside in the carboxyterminal domain of the NF200 polypeptide as defined by immunoreaction with limited chymotryptic fragments. Immunohistochemical studies of bovine cerebellum, spinal cord, trigeminal ganglion, and trigeminal nerve with these new monoclonal antibodies demonstrate immunoreactivity primarily in neuronal perikarya; axons and dendrites are weakly or infrequently immunostained. After enzymatic dephosphorylation of these tissues, a more extensive distribution of immunoreactivity is seen, especially in axons and dendrites. Immunostaining of cultured rat sympathetic neurons is restricted to cell bodies. These data provide evidence for the in situ existence of NF200 epitopes that are not phosphorylated in some classes of neurons or regions of a neuron, but are modified by phosphorylation in other neurons or neuronal domains. These new monoclonal antibodies are distinctly different from those in a large library (over 100) raised to, and specific for, phosphorylated neurofilament proteins. They are novel tools for probing neurofilament distribution, metabolism, structure, and possibly function.