Accumulation of amyloid beta and tau and the formation of neurofilament inclusions following diffuse brain injury in the pig.

Brain trauma in humans increases the risk for developing Alzheimer disease (AD) and may induce the acute formation of AD-like plaques containing amyloid beta (A beta). To further explore the potential link between brain trauma and neurodegeneration, we conducted neuropathological studies using a pig model of diffuse brain injury. Brain injury was induced in anesthetized animals via nonimpact head rotational acceleration of 110 degrees over 20 ms in the coronal plane (n = 15 injured, n = 3 noninjured). At 1, 3, 7, and 10 days post-trauma, control and injured animals were euthanized and immunohistochemical analysis was performed on brain sections using antibodies specific for A beta, beta-amyloid precursor protein (betaPP), tau, and neurofilament (NF) proteins. In addition to diffuse axonal pathology, we detected accumulation of A beta and tau that colocalized with immunoreactive betaPP and NF in damaged axons throughout the white matter in all injured animals at 3-10 days post-trauma. In a subset of brain injured animals, diffuse A beta-containing plaque-like profiles were found in both the gray and white matter, and accumulations of tau and NF rich inclusions were observed in neuronal perikarya. These results show that this pig model of diffuse brain injury is characterized by accumulations of proteins that also form pathological aggregates in AD and related neurodegenerative diseases.     

Studies of neurofilaments that accumulate in proximal axons of rats intoxicated with β,β′-iminodipropionitrile (IDPN)

The paradigm of IDPN neuropathy was produced in rats in order to examine the neurofilaments (NFs) that accumulate in the proximal motor and sensory axons of intoxicated animals, and to compare the aggregated NFs with control NFs and with the depleted populations of NFs in the distal portions of the same experimental nerves. NFs were probed biochemically and histochemically, using a large and well-characterized library of monoclonal antibodies that included antibodies that are monospecific for each of the rat NF protein subunits (NF-H, NF-M, and NF-L) as well as antibodies that recognized differential phosphorylated states of rat NF-H and NF-M. All antibodies tested showed enhanced immunostaining of enlarged axons and of large spheroids in the spinal cord and dorsal root ganglia of experimental animals. Biochemical analyses of IDPN-treated animals revealed enrichment of NF-H, NF-M, and NF-L in homogenates of dorsal root ganglia and of proximal motor and sensory nerve roots as well as depletion of the three subunits in distal nerve roots and in sciatic nerves. Immunoblots revealed a uniform enrichment of NF-H, NF-M, and NF-L in NF aggregates as well as the same admixture of phosphorylated and dephosphorylated epitopes of NF-H and NF-M in experimental and in control tissues. The global increase of immunoreactivity in axonal swellings to antibodies that react with phosphorylated, nonphosphorylated,and phosphorylation-independent NF epitopes suggests that IDPN induces an accumulation of NFs in proximal axons without necessarily altering the state of NF phosphorylation.     

Two-stage expression of neurofilament polypeptides during rat neurogenesis with early establishment of adult phosphorylation patterns

Monoclonal antibodies (mAbs) to rat neurofilament (NF) proteins NF-L, NF-M, and NF-H were used to examine the developmental programs of NF expression in rat embryos. The ability of these mAbs to recognize differentially phosphorylated states of NF-M and NF-H (Lee et al., 1987, the preceding paper) was exploited in order to examine the temporal and spatial patterns of NF phosphorylation during early neuronal development in vivo. NF proteins were first detected on the twelfth day postfertilization (E12) using NF-L- or NF-M-specific mAbs. By E13, the coexpression of NF-L and NF-M was widespread, reflecting dramatic increases of immunoreactivity to both subunits. Partial phosphorylation, denoted P[+], of NF-M was already present in perikarya and neurites of E12 neurons. Extensively phosphorylated, or P[+++], isoforms of NF-M appeared in E13 axons, thereby establishing a proximodistal gradient of NF phosphorylation during the earliest phase of NF expression. Immunoblots of tissue homogenates revealed that most NF-M of E13 embryos exists in a partially phosphorylated, or P[+], isoform. Unequivocal staining for NF-H first appeared at E15, a time at which NF-L and NF-M had already attained their adult patterns of immunocytochemical staining. Levels of NF-H were extremely low at E15 but could be detected in all of its differentially phosphorylated states, i.e., nonphosphorylated P[-], partly P[+], and highly P[+++] phosphorylated isoforms. P[+++] isoforms of NF-H were restricted to the distal portions of E15 axons, although staining of more proximal axons, like those in adult, was noted by E17. Immunoblots of E17 embryos revealed most NF-H as P[-] and P[+] isoforms. Quantities of immunoreactive NF-H increased very slowly and remained well below those of NF-M and NF-L for several weeks beyond birth. These results show that sequential forms of NFs are expressed by developing and maturing neurons throughout the nervous system. An "immature" form of NFs, composed of NF-M and NF-L, appears to function in establishing the neuronal phenotype and in initiating and maintaining neurite outgrowth. Addition of NF-H confers a "mature" state to the NF. This delayed expression of NF-H is a slow and graduated process that coincides in time with the stabilization of neuronal circuitries and may be important in modulating axonal events, such as the slowing of cytoskeletal transport and the growth of axonal caliber.     

Neurofilaments of aged rats: the strengthened interneurofilament interaction and the reduced amount of NF-M.

Amyotrophic lateral sclerosis is an age-related neurological disease, characterized by neurofilament (NF) accumulation in primary axons followed by degeneration of motor neurons. To elucidate age-related factors that might lead to pathological NF accumulation, NFs were compared between young and aged rats. Electron microscopic examination of sciatic nerve axons revealed that NFs were more than twice as densely packed in aged rat axons (542 +/- 180 NFs/mm2) as in young adult rat axons (211 +/- 73 NFs/mm2). The NFs isolated from aged rats also appeared to be more aggregated than those from young rats. Phosphorylation at the head or tail domains was studied as a possible candidate affecting NF organization. Western blotting with phosphorylation-dependent antibodies showed higher phosphorylation of NF-H in the tail domains of aged rat spinal cord NFs, but dephosphorylation did not diminish the differences in aggregation between aged and young rat NFs. On the other hand, when NFs were phosphorylated by A-kinase on their head domains, the extent of phosphorylation in NF-M of aged rat NFs was only one-third of young rat NFs. We found that aged rat NFs contained only 60% of the NF-M of young rat NFs in molar ratio compared to NF-L. These results raise a possibility that the decreased amount of NF-M induces the aggregates of isolated NFs and the higher packing density of NF in aged rat axons.     

Altered tubulin and neurofilament expression and impaired axonal growth in diabetic nerve regeneration

Cytoskeletal protein expression in sensory neurons and sciatic nerve axonal growth were examined in type 1 diabetic BB/Wor rats after sciatic nerve crush injury. Diabetic male rats were subjected to sciatic nerve crush at 6 wk of diabetes. L4 and L5 dorsal root ganglia (DRG) mRNA expression of low and medium molecular weight neurofilaments (NF-L, NF-M), betaII- and betaIII-tubulin as well as protein expression of NF-L, NF-M, and beta-tubulin were examined at various time points following crush injury and compared with age- and sex-matched non-diabetic BB/Wor rats. Steady state mRNA expression of NF-L, NF-M, betaII- and betaIII-tubulin were decreased in diabetic DRG. NF-L and NF-M proteins were also decreased in DRG of uncrushed diabetic animals. After crush injury, betaII- and betaIII-tubulin mRNA were upregulated in control animals at day 2 and day 6, respectively, and beta-tubulin protein showed similarly increased expression after crush injury, while such upregulations did not occur in diabetic animals. Conversely, mRNA and protein expressions of NF-L, NF-M were downregulated to a lesser extent in diabetic animals compared to control rats. These changes were associated with impaired axonal elongation and caliber growth of regenerating fibers in diabetic rats. We propose that upregulation of tubulin has a negative feedback on NF expression in response to nerve injury, as seen in control rats. The absence of this upregulation in diabetic animals may impair its regulatory effect on NF expression and contribute to perturbed nerve regeneration seen in diabetic nerve.     

Individual neurofilament subunits reassembled in vitro exhibit unique biochemical, morphological and immunological properties

Purified bovine neurofilament (NF) subunit proteins were reassembled in vitro to form either homopolymeric or heteropolymeric intermediate-sized filaments using single or paired combinations of NF triplet proteins. Using conditions established for the reassembly of bovine NF triplet proteins, we demonstrated that the low Mr NF subunit (NF-L) alone and in combination with the middle Mr NF subunit (NF-M) reassembled very efficiently, i.e. greater than 95% of these proteins formed filaments within 90 min from the start of reassembly. In contra-distinction, the high Mr NF subunit (NF-H) alone and in combination with NF-M or NF-L underwent reassembly to a lesser extent, i.e. 62-88% of these proteins reassembled within 90 min. Immunolabeling of the reassembled NF polymers revealed striking differences in the organization of rod domain determinants. Specifically, antibodies specific for epitopes in the rod domains of NF-H, NF-M and NF-L failed to bind heteropolymeric filaments but recognized rod domains in the homopolymers. In contrast, antibodies specific to head and tail domains of all NF proteins labeled the reassembled hetero- and homopolymeric NFs. Double-labeling of heteropolymers demonstrated that pairs of different NF subunits coassembled into intermediate-sized filaments. Our results also showed that only copolymeric filaments of NF-L and NF-M, but not NF-L/NF-H and NF-M/NF-H were able to form long and stable 10-nm wide filaments. These observations provide new insights into the requirements for stable filament formation from NF subunits. In particular, they support the notion that only NF-L/NF-M, but not NF-L/NF-H or NF-M/NF-H might assemble into a stable filamentous network in vivo.     

Altered expression of neurofilament subunits in diisopropyl phosphorofluoridate-treated hen spinal cord and their presence in axonal aggregations

Diisopropyl phosphorofluoridate (DFP) is an organophosphorus ester, which produces organophosphorus ester-induced delayed neuropathy (OPIDN) in hen and other sensitive species. A single dose of DFP (1.7 mg/kg, sc.) produces mild ataxia in 7-14 days in hens, which develops into severe ataxia or paralysis with the progression of disease. OPIDN is associated with axonal swellings and degeneration of axons. This study was carried out to investigate the expression of neurofilament (NF) subunits in the spinal cord of DFP-treated hens. Hens were treated with a single dose of DFP and sacrificed 1, 5, 10, and 20 days post-treatment. Western blot analysis showed increased expression of middle molecular weight neurofilament protein (NF-M), and decreased expression of high molecular weight (NF-H) and low molecular weight (NF-L) neurofilament proteins in the 2 M urea extracts of spinal cord particulate fraction. These changes were observed within 24 h of DFP administration and persisted for 10-20 days. Thus, there was increase in the stoichiometry of NF-M:NF-L in the spinal cord of DFP-treated hens. Immunoprecipitation, cross-linking, and two-dimensional polyacrylamide gel electrophoresis showed the presence of heterodimers, but not heterotetramers, in the hen spinal cord extract. Immunohistochemical staining revealed the presence of all three NF subunits in the cytoskeletal inclusions in DFP-treated hen spinal cord cross-sections. The results suggested that each NF subunit might be accumulated by a different mechanism in the axonal aggregations of DFP-treated hen.     

Accumulation of β-amyloid precursor protein and ubiquitin in axons after spinal cord trauma in humans: immunohistochemical observations on autopsy material

We evaluated by immunohistochemistry the presence of β-amyloid precursor protein (ßAPP) and ubiquitin-like material which may accumulate in axons of the human spinal cord subjected to injury. Autopsy material was obtained from nine cases with different types of trauma: breech delivery with neonatal spinal injury, compression of the cord induced by fractures of the vertebral column, haematomas or intradural meningioma. The post-trauma period ranged from 10 days to several years. The spinal cord of six control cases without evidence of injury presented βAPP immunoreactivity in nerve cell bodies and in a few axonal profiles but not in dendrites. Seven of the nine cases with spinal cord trauma showed an accumulation of βAPP-immunoreactive material in axons of the longitudinal tracts at the site of the injury. Five cases presented similar axonal immunoreactivity in the grey matter of the cord. Ubiquitin-like immunoreactivity was present in expanded axons in cases with spinal cord injury. Cases with spinal cord trauma thus present βAPP-immunoreactive axons particularly of the longitudinal tracts in the same way as in trauma to rat spinal cord and in various brain injuries. The aggregation of βAPP-immunoreactive material indicates disturbed axonal transport of βAPP. Accumulation of ubiquitin-like immunoreactive material in expanded axons at the site of trauma may be one prerequisite for degradation of abnormal proteins by the ubiquitin-mediated proteolytic pathway.     

Participation of neurofilament proteins in axonal dark degeneration of rat's optic nerves

Neurofilaments (NF) are neuronal intermediate filaments formed by three different subunits: high (NF-H), medium (NF-M) and light (NF-L). They are responsible for the determination and maintenance of axon caliber. Accumulation of NF or their immunoreactive products are components of several neurodegenerative disease lesions, such as neurofibrillary tangles, Lewy bodies and the spheroids of amyotrophic lateral sclerosis. Also, cytoskeletal breakdown is one of the first ultrastructural changes occurring after nerve crush or section. In the present study, Wistar rats were subjected to bilateral enucleation to induce Wallerian degeneration of optic nerve fibers and perfused 24 h, 48 h and 1 week later. Optic nerve segments were processed for electron microscopy (EM), light microscopy immunofluorescence (LM) and immunoelectronmicroscopy (IEM) for NF subunit detection. LM for NF of control nerves showed a slightly different pattern and intensity for each subunit, with more intense staining of NF-M and NF-H and less intense staining of NF-L. This reaction did not change considerably at 48 h, but was severely reduced 1 week after enucleation. Results of EM showed fibers in: (1) partial cytoskeleton degeneration or (2) watery degeneration or (3) dark degeneration. The number of dark degenerating axons was statistically higher at the latest time-interval studied. Neurofilament clumping areas and dark degenerating axons showed positive immunostaining for the three neurofilaments subunits when examined by IEM. These results suggest that dark degenerating axons develop from areas of neurofilament aggregation. We may also conclude that NF proteins participate in the process of axonal dark degeneration.     

Alteration of the neurofilament sidearm and its relation to neurofilament compaction occurring with traumatic axonal injury

Traumatic injury evokes two characteristic forms of focal axonal injury, one of which involves focal perturbation of axolemmal permeability associated with rapid compaction of the underlying axonal neurofilament lattice and microtubular loss. In this process, the neurofilament sidearms have been the subject of intense scrutiny in relation to their role in this NF compaction, with the suggestion that the sidearms, thought to maintain interfilament distance, are proteolytically cleaved and degraded at the time of injury. The current communication addresses the fate of the NF sidearms in such injured axons. Adult cats were subjected to moderate/severe fluid percussion brain injury after intrathecal administration of horseradish peroxidase (HRP). This tracer, excluded by the intact axolemma of uninjured axons, was used to recognize injured axons via HRP intra-axonal uptake/flooding with HRP. Animals were perfused and processed for light microscopic and electron microscopic study of both HRP-containing and non-HRP-containing axons from the same field. HRP-containing axons consistently displayed evidence of traumatically-induced (NF) cytoskeletal collapse. Electron micrographs of HRP-containing axons as well as uninjured, non-HRP-containing axons from the same fields were videographically captured, digitized, enlarged and analysed for NF sidearm length and NF density. HRP-containing axons were found to have increased NF density. Surprisingly, this increased NF density occurred despite the retention of the NF sidearms, which now, however, were reduced in height in comparison to the non-HRP-containing uninjured axons. These observations are not consistent with previously published reports suggesting that overt proteolytic degradation of sidearms was responsible for NF compaction. Based on our findings, we suggest that the NF compaction associated with traumatically-induced axolemmal permeability changes may have its genesis in more subtle sidearm modification, perhaps involving a change in phosphorylation state.     

Overexpression of neurofilament subunit M accelerates axonal transport of neurofilaments

Neurofilaments are composed of three polypeptide subunits (NF-H, NF-M and NF-L). They are the most abundant cytoskeletal element in large myelinated axons and play a central role in development of axonal caliber. To perform this role, neurofilaments are transported from their site of synthesis, the cell bodies, to the distal axons. Previous studies showed that overexpression of NF-M in transgenic mice led to accumulation of neurofilaments in neurons and a reduction in the number of neurofilaments in axons, suggesting that axonal transport of neurofilaments was slowed. To determine whether this was the case, we measured axonal transport velocities in the wild type and transgenic mice overexpressing NF-M by the classical pulse-labeling method using 35S-methionine. We found that neurofilament transport in peripheral motor axons can be described with a model consistent with two linear velocities. Contrary to expectations, both velocities were accelerated by overexpression of NF-M. These results suggest that subunit composition in neurofilaments play a regulatory role in neurofilament transport. In addition, these results show that there are regional differences in neurofilament transport along long axons and these differences may be the basis for selective regional accumulation of neurofilaments in various neurological disorders.     

Sequence variants in human neurofilament proteins: Absence of linkage to familial amyotrophic lateral sclerosis

Neurofilaments, assembled from NF-L (68 Kd), NF-M (95 Kd), and NF-H (115 kd), are the most abundatn structural components in large myelinated axons, particularly those of motor neurons. Aberrant neurofilament accumulation in cell bodies and axons of motor neurons is a prominent pathological feature of several motor neuron diseases, including sporadic and familial amyotrophic lateral sclerosis (ALS). Transgenic methods have proved in mice that mutation in or increased expression of neurofilament subunits can be primary causes of motor neuron disease that mimics the neurofilamentous pathology often reported in human disease. To examine whether mutation in neurofilament subunits causes or predisposes to ALS, we used single-strand conformation polymorphism coupled with DNA sequencing to search for mutations in the entirety of the human NF-L, NF-M, and NF-H genes from 100 familial ALS patients known not to carry mutations in superoxide dismutase 1 (SOD1), as well as from 75 sporadic ALS patients. Six polypeptide sequence variants were identified in rod and tail domains of NF-L, NF-M, or NF-H. However, all were found at comparable frequency in DNAs from normal individuals and no variant cosegregated with familial disease. Two deletions found previously in NF-H genes of sporadic ALS patients were not seen in this group of familial or sporadic ALS patiens.     

Quantitative evaluation of microscopic injury with diffusion tensor imaging in a rat model of diffuse axonal injury

Diffuse axonal injury (DAI) is the predominant effect of severe traumatic brain injury and contributes significantly to neurological deficits. However, it is difficult to diagnose or characterize non-invasively with conventional imaging. Our study provides significant validation of a visual and statistical diffusion tensor imaging (DTI) technique as compared with pathological and electron microscopic study in a rat DAI model at multiple predilection sites and time points following trauma. Two DTI parameters, fractional anisotropy (FA) and axial diffusivity (AD), were significantly reduced from 12 h to 5 days post-trauma, corresponding to pathological axonal injury. At 7 days post-trauma, FA remained decreased, whereas AD pseudo-normalized and radial diffusivity increased. The temporal alterations in DTI parameters were observed in multiple predilection sites, and the extent of the changes in these parameters correlated significantly with the severity of histologically visualized axonal injury, as assessed by integrated optical density of immunochemically stained injured axons with quantitative stereology. Although anatomical T2-weighted magnetic resonance images showed no abnormal signals in microscopic lesions, we detected and characterized axonal injury directly by DTI at each time point. These results demonstrate that DTI has significant potential as a non-invasive tool with which to quantitatively diagnose and evaluate microstructural injury in the experimental and clinical assessment of DAI. This method can assist in accurate evaluation of the extent of axonal injury, detection of severe predilection foci, determination of approximate time of injury, and monitoring of the pathogenic condition at the early post-injury stage.     

Structure, biological activity of the upstream regulatory sequence, and conserved domains of a middle molecular mass neurofilament gene of Xenopus laevis

During development, the molecular compositions of neurofilaments (NFs) undergo progressive modifications that correlate with successive stages of axonal outgrowth. Because NFs are the most abundant component of the axonal cytoskeleton, understanding how these modifications are regulated is essential for knowing how axons control their structural properties during growth. In vertebrates ranging from lamprey to mammal, orthologs of the middle molecular mass NF protein (NF-M) share similar patterns of expression during axonal outgrowth, which suggests that these NF-M genes may share conserved regulatory elements. These elements might be identified by comparing the sequences and activities of regulatory domains among the vertebrate NF-M genes. The frog, Xenopus laevis, is a good choice for such studies, because its early neural development can be observed readily and because transgenic embryos can be made easily. To begin such studies, we isolated genomic clones of Xenopus NF-M(2), tested the activity of its upstream regulatory sequence (URS) in transgenic embryos, and then compared sequences of regulatory regions among vertebrate NF-M genes to search for conserved elements. Studies with reporter genes in transgenic embryos found that the 1. 5 kb URS lacked the elements sufficient for neuron-specific gene expression but identified conserved regions with basal regulatory activity. These studies further demonstrated that the NF-M 1.5 kb URS was highly susceptible to positional effects, a property that may be relevant to the highly variant, tissue-specific expression that is seen among members of the intermediate filament gene family. Non-coding regions of vertebrate NF-M genes contained several conserved elements. The region of highest conservation fell within the 3' untranslated region, a region that has been shown to regulate expression of another NF gene, NF-L. Transgenic Xenopus may thus prove useful for testing further the activity of conserved elements during axonal development and regeneration.     

Neurofilament mRNAs are present and translated in the normal and severed sciatic nerve

Local protein synthesis within axons has been studied on a limited scale. In the present study, several techniques were used to investigate this synthesis in sciatic nerve, and to show that it increases after damage to the axon. Neurofilament (NF) mRNAs were probed by RT-PCR, Northern blot and in situ hybridization in axons of intact rat sciatic nerve, and in proximal or distal stumps after sciatic nerve transection. RT-PCR demonstrated the presence of NF-L, NF-M and NF-H mRNAs in intact sciatic nerve, as well as in proximal and distal stumps of severed nerves. Northern blot analysis of severed nerve detected NF-L and NF-M, but not NF-H. This technique did not detect the three NFs mRNAs in intact nerve. Detection of NF-L and NF-M mRNA in injured nerve, however, indicated that there was an up-regulation in response to nerve injury. In situ hybridization showed that NF-L mRNA was localized in the Schwann cell perinuclear area, in the myelin sheath, and at the boundary between myelin sheath and cortical axoplasm. RNA and protein synthesizing activities were always greater in proximal as compared to distal stumps. NF triplet proteins were also shown to be synthesized de novo in the proximal stump. The detection of neurofilament mRNAs in nerves, their possible upregulation during injury and the synthesis of neurofilament protein triplet in the proximal stumps, suggest that these mRNAs may be involved in nerve regeneration, providing a novel point of view of this phenomenon.     

Differential expression and localization of the phosphorylated and nonphosphorylated neurofilaments during the early postnatal development of rat hippocampus

Neurofilament (NF) proteins are expressed in most mature neurons in the central nervous system. Although they play a crucial role in neuronal growth, organization, shape, and plasticity, their expression pattern and cellular distribution in the developing hippocampus remain unknown. In the present study, we have used Western blotting and immunocytochemistry to study the low- (NF-L), medium- (NF-M), and high- (NF-H) molecular-weight NF proteins; phosphorylated epitopes of NF-M and NF-H; and a nonphosphorylated epitope of NF-H in the early postnatal (through P1-P21) development of the rat hippocampus. During the first postnatal week, NF-M was the most abundantly expressed NF, followed by NF-L, whereas the expression of NF-H was very low. Through P7-P14, the expression of NF-H increased dramatically and later began to plateau, as also occurred in the expression of NF-M and NF-L. At P1, no NF-M immunopositive cell bodies were detected, but cell processes in the CA1-CA3 fields were faintly immunopositive for NF-M and for the phosphorylated epitopes of NF-M and NF-H. At P7, CA3 pyramidal neurons were strongly immunopositive for NF-L and NF-H, but not for NF-M. The axons of granule cells, the mossy fibers (MFs), were NF-L and NF-M positive through P7-P21 but were NF-H immunonegative at all ages. Although they stained strongly for the phosphorylated NF-M and NF-H at P7, the staining intensity sharply decreased at P14 and remained so at P21. The cell bodies of CA1 pyramidal neurons and granule cells remained immunonegative against all five antibodies in all age groups. Our results show a different time course in the expression and differential cell type and cellular localization of the NF proteins in the developing hippocampus. These developmental changes could be of importance in determining the reactivity of hippocampal neurons in pathological conditions in the immature hippocampus.     

mRNA levels of all three neurofilament proteins decline following nerve transection

The control of neurofilament (NF) protein gene expression was studied by determining and comparing the levels of mRNA to the heavy (NF-H), mid-sized (NF-M) and light (NF-L) NF protein subunits in rat dorsal root ganglia (DRG) following sciatic nerve transection. mRNA to NF-H (4.5 kb), to NF-M (3.4 kb) and to NF-L (2.5 and 4.0 kb) were identified in Northern blots and quantitated in dot blot analyses, using specific cDNA probes for each NF protein. Following transection and continuing for at least 28 days. The early and co-terminal fall in mRNAs suggests that the 3 NF genes are regulated by common factor(s) and that the function of these factor(s) is influenced by the state of axonal continuity with the target organ.     

Cloning and developmental expression of the murine neurofilament gene family

DNA clones encoding the 3 mouse neurofilament (NF) genes have been isolated by cross-hybridization with a previously described NF-L cDNA probe from the rat. Screening of a lambda gt10 cDNA library prepared from mouse brain RNA led to the cloning of an NF-L cDNA of 2.0 kb that spans the entire coding region of 541 amino acids and of an NF-M cDNA that covers 219 amino acids from the internal alpha-helical region and the carboxy-terminal domains of the protein. These cDNA clones were used as probes to screen mouse genomic libraries, and cosmid clones containing both NF-L and NF-M sequences were isolated as well as overlapping cosmids containing the NF-H gene. This strongly suggests that the 3 neurofilament genes are organised in a cluster and derived by gene duplication of a common ancestral gene. RNA blot analyses using specific DNA probes for each of the genes indicate that NF mRNAs are differentially expressed during brain development. The NF-L and NF-M mRNAs are detected early in the embryonal brain, with a progressive increase in their levels during development, while the NF-H mRNA is barely detectable at embryonal stages and accumulates later in the postnatal brain.     

Multiple proteins implicated in neurodegenerative diseases accumulate in axons after brain trauma in humans

Studies in animal models have shown that traumatic brain injury (TBI) induces the rapid accumulation of many of the same key proteins that form pathologic aggregates in neurodegenerative diseases. Here, we examined whether this rapid process also occurs in humans after TBI. Brain tissue from 18 cases who died after TBI and from 6 control cases was examined using immunohistochemistry. Following TBI, widespread axonal injury was persistently identified by the accumulation of neurofilament protein and amyloid precursor protein (APP) in axonal bulbs and varicosities. Axonal APP was found to co-accumulate with its cleavage enzymes, beta-site APP cleaving enzyme (BACE), presenilin-1 (PS1) and their product, amyloid-beta (Abeta). In addition, extensive accumulation of alpha-synuclein (alpha-syn) was found in swollen axons and tau protein was found to accumulate in both axons and neuronal cell bodies. These data show rapid axonal accumulation of proteins implicated in neurodegenerative diseases including Alzheimer's disease and the synucleinopathies. The cause of axonal pathology can be attributed to disruption of axons due to trauma, or as a secondary effect of raised intracranial pressure or hypoxia. Such axonal pathology in humans may provide a unique environment whereby co-accumulation of APP, BACE, and PS1 leads to intra-axonal production of Abeta as well as accumulation of alpha-syn and tau. This process may have important implications for survivors of TBI who have been shown to be at greater risk of developing neurodegenerative diseases.     

Early posttranslational modifications of the three neurofilament subunits in mouse retinal ganglion cells: neuronal sites and time course in relation to subunit polymerization and axonal transport

We have characterized stages in the posttranslational processing of the three neurofilament subunits, High (NF-H), Middle (NF-M), and Low (NF-L), in retinal ganglion cells in vivo during the interval between synthesis in cell bodies within the retina and appearance of these polypeptides in axons at the level of the optic nerve (optic axons). Neurofilament proteins pulse-labeled by injecting mice intravitreally with [35S]methionine or [32P]orthophosphate, were isolated from Triton-soluble and Triton-insoluble fractions of the retina or optic axons by immunoprecipitation or immunoaffinity chromatography. Within 2 h after [35S]methionine injection, the retina contained neurofilament-immunoreactive radiolabeled proteins with apparent molecular weights of 160, 139, and 70 kDa, which co-migrated with subunits of axonal neurofilaments that were dephosphorylated in vitro with alkaline phosphatase. The two larger polypeptides were not labeled with [32P]orthophosphate, indicating that they were relatively unmodified forms of NF-H and NF-M. About 75% of the subunits were Triton-insoluble by 2 h after isotope injection, and this percentage increased to 98% by 6 h. Labeled neurofilament polypeptides appeared in optic axons as early as 2 h after injection. These subunits exhibited apparent molecular weights of 160, 139, and 70 kDa and were Triton-insoluble. The time of appearance of fully modified polypeptide forms differed for each subunit (2 h for NF-L, 6-18 h for NF-M, 18-24 h for NF-H) and was preceded by the transient appearance of intermediate forms. The modified radiolabeled subunits in optic axons 3 days after synthesis were heavily labeled with [32P]orthophosphate and exhibited the same apparent molecular weights as subunits of axonal neurofilaments (70 kDa, 145 and 140 kDa, and 195-210 kDa, respectively). Whole mounts of retina immunostained with monoclonal antibodies against NF-H in different states of phosphorylation demonstrated a transition from non-phosphorylated neurofilaments to predominantly phosphorylated ones within a region of the axon between 200 and 1000 microns downstream from the cell body. These experiments demonstrate that the addition of most phosphate groups to NF-M and NF-H takes place within a proximal region of the axon. The rapid appearance of modified forms of NF-L after synthesis may imply that processing of this subunit occurs at least partly in the cell body. The presence of a substantial pool of Triton-insoluble, unmodified subunits early after synthesis indicates that the heaviest incorporation of phosphate occurs after neurofilament proteins are polymerized.(ABSTRACT TRUNCATED AT 400 WORDS)