Smaller axon and unaltered numbers of microtubules per axon in relation to number of myelin lamellae of myelinated fibers in the mutant quail deficient in neurofilaments

To characterize the morphological features of the myelinated fibers in the mutant quails deficient in neurofilaments (NF), caused by a nonsense mutation in the NF-L gene, the morphological parameters of the axon and myelin sheath, and their relationships in the peroneal nerve were evaluated. In the mutant, the axonal area was smaller than in the control (P>0.01), reflecting the lack of large diameter axons. There was no significant difference in the mean number of myelin lamellae and of their spacings between controls and mutants. Therefore, it was decided to analyze the alteration of axonal parameters in relation to the number of myelin lamellae. In the regression analysis, the number of microtubules (MT) per square micrometer of the axonal area was greater in the mutant than in the control (P<0.05); however, the number of MT per axon was similar in controls and mutants with the same given number of myelin lamellae. The number of MT+NF per axon was smaller in the mutant than in the control only for myelinated fibers with more than 25 myelin lamellae (P>0.05). These findings indicate that there was a less significant effect of NF deficiency on the smaller than on the larger myelinated fibers. There was no compensatory increase in the numbers of MT per axon of the myelinated fibers in the mutant as found previously in the unmyelinated fibers of the mutant.     

Mice with a mutation in the dynein heavy chain 1 gene display sensory neuropathy but lack motor neuron disease

In neurons, cytoplasmic dynein functions as a molecular motor responsible for retrograde axonal transport. An impairment of axonal transport is thought to play a key role in the pathogenesis of neurodegenerative diseases such as amyotrophic lateral sclerosis, the most frequent motor neuron disease in the elderly. In this regard, previous studies described two heterozygous mouse strains bearing missense point mutations in the dynein heavy chain 1 gene that were reported to display late-onset progressive motor neuron degeneration. Here we show, however, that one of these mutant strains, the so-called Cra mice does not suffer from motor neuron loss, even in aged animals. Consistently, we did not observe electrophysiological or biochemical signs of muscle denervation, indicative of motor neuron disease. The «hindlimb clasping» phenotype of Cra mice could rather be due to the prominent degeneration of sensory neurons associated with a loss of muscle spindles. Altogether, these findings show that dynein heavy chain mutation triggers sensory neuropathy rather than motor neuron disease.     

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.     

Local control of axonal properties by Schwann cells: neurofilaments and axonal transport in homologous and heterologous nerve grafts.

A number of axonal properties, including slow axonal transport and neurofilament phosphorylation, are altered in a mutant mouse strain with a Schwann cell deficiency, the Trembler. The Trembler phenotype is associated with poor myelination and reduced axonal caliber in the peripheral nervous system, but the genetic lesion has not yet been identified. To determine whether changes in axonal properties resulted from a direct action of Schwann cells on the axon, a segment of sciatic nerve from myelin-deficient Trembler mouse was grafted into the sciatic nerve of a normal mouse and normal axons were allowed to regenerate. Normal axons surrounded by Trembler Schwann cells are reduced in diameter, but resume their original diameter distal to the graft. Neurofilament transport was also affected locally in sciatic nerves with Trembler grafts into normal nerve. The velocity of neurofilament transport was not significantly different from controls in portions of the nerve proximal to the Trembler graft, but there was a reduction in neurofilament transport rates upon entering the Trembler graft. This was accompanied by an increase in the ratio of neurofilament over tubulin in the case of the Trembler graft, suggesting both a slowing of the neurofilament and an increase in the rate of tubulin transport. Using heterologous grafts of Trembler nerve segments into wildtype nerves, Schwann cells were shown to locally influence axonal caliber, neurofilament organization, and slow axonal transport. These observations emphasize the importance of glial cells in modulating neuronal structure and functions, as well as focusing attention on the role of glia in the etiology of neuropathologies that alter the neuronal environment.     

Regulation of aberrant neurofilament phosphorylation in neuronal perikarya. II. Correlation with continued axonal elongation following axotomy.

Neurofilaments (NF) are normally poorly phosphorylated in neuronal perikarya and highly phosphorylated in axons. Aberrant NF phosphorylation in the neuronal perikaryon has been demonstrated in a number of human and experimental disorders. In this study, we have asked whether expression of these phosphorylated NF (pNF) epitopes is dependent upon continued axonal regeneration following nerve transection (axotomy). This hypothesis was tested using the neurotoxic chemical acrylamide (AC) which is known to inhibit axonal regeneration following systemic administration. First, we examined whether AC acts at the level of the neuronal perikaryon to inhibit axonal elongation. Systemic, high dose intraperitoneal (IP) AC administration totalling 150 mg/kg (75 mg/kg x 2) did not impair the axotomy-induced reordering of slow axonal transport in the neuronal perikaryon. Next, we studied the ability of AC to directly prevent nerve outgrowth at the growing tips of axons. Subperineurial injection of AC (0.1 M), which in preliminary studies was found not to produce nerve fiber damage, markedly reduced the extent of nerve outgrowth when injected proximal to a nerve crush; this was shown by a reduction in the extent of radiolabeling and number of axonal sprouts in the distal stump seven days following nerve crush. Using this protocol, a 67% decrease in the number of neuronal perikarya in the L4 and L5 dorsal root ganglia demonstrating immunoreactivity to antibody 07-05 (directed against pNF epitopes) was observed in AC-injected compared to contralateral saline-injected crushed nerves. Taken together, the results indicate that inhibition of axonal regeneration in the distal stump by AC reduces aberrant NF phosphorylation in the neuronal perikaryon following axotomy.     

Mice with reduced brain-derived neurotrophic factor expression show decreased choline acetyltransferase activity, but regular brain monoamine levels and unaltered emotional behavior

The "neurotrophin hypothesis" of depression predicts that depressive disorders in humans coincide with a decreased activity and/or expression of brain-derived neurotrophic factor (BDNF) in the brain. Therefore, we investigated whether mice with a reduced BDNF expression due to heterozygous gene disruption demonstrate depression-like neurochemical changes or behavioral symptoms. BNDF protein levels of adult BDNF(+/-) mice were reduced to about 60% in several brain areas investigated, including the hippocampus, frontal cortex, striatum, and hypothalamus. The content of monoamines (serotonin, norepinephrine, and dopamine) as well as of serotonin and dopamine degradation products was unchanged in these brain regions. By contrast, choline acetyltransferase activity was significantly reduced by 19% in the hippocampus of BDNF(+/-) mice, indicating that the cholinergic system of the basal forebrain is critically dependent on sufficient endogenous BDNF levels in adulthood. Moreover, BDNF(+/-) mice exhibited normal corticosterone and adrenocorticotropic hormone (ACTH) serum levels under baseline conditions and following immobilization stress. In a panel of behavioral tests investigating locomotor activity, exploration, anxiety, fear-associated learning, and behavioral despair, BDNF(+/-) mice were indistinguishable from wild-type littermates. Thus, a chronic reduction of BDNF protein content in adult mice is not sufficient to induce neurochemical or behavioral alterations that are reminiscent of depressive symptoms in humans.     

Tyrosinated and detyrosinated microtubules in axonal processes of cerebellar macroneurons grown in culture.

We have used the monoclonal antibody YL 1/2 (Tyr) specific for tyrosinated tubulin, and a polyclonal antibody (Glu) specific for detyrosinated tubulin to visualize the distribution of microtubules and microtubule assembly sites during axonal outgrowth. Cerebellar macroneurons growing in culture initially extend several short and thin neurites which have the potential to differentiate either as axons or dendrites (Ferreira and Caceres: Developmental Brain Research 49:205-213, 1989). At the onset of axonal outgrowth the Tyr antibody labels the minor neurites, the axon, and its growth cone, while the Glu antibody only shows immunoreactivity in the axonal shaft. After nocodazole treatment, the Tyr staining disappears, whereas that produced by the Glu antibody remains practically unchanged. When nocodazole was removed, tyrosinated microtubules reappeared first at the tip of the axon, in a more distal region than that occupied by detyrosinated microtubules; another focal site of tyrosinated tubulin incorporation was detected in the cell body. Incorporation of tyrosinated tubulin into growing axons was also studied after taxol treatment. After long incubation periods in the presence of taxol, the Tyr staining disappeared from the axon but remained in the cell body; however, immunoreactivity in this site was negative when the cells were preincubated in the presence of protein synthesis inhibitors. Release from taxol results in the reappearance of Tyr immunoreactivity at the distal end of the axon. Taken collectively, the present results indicate 1) that in cerebellar macroneurons axonal differentiation is accompanied by a temporal and spatial differentiation of microtubules and 2) that there is an active site of tyrosinated tubulin assembly at the tip of axonal processes, and they suggest that the highly tyrosinated domain in this region is a consequence of rapid microtubule turnover and tubulin tyrosine ligase activity.     

IgG monoclonal proteins from patients with axonal peripheral neuropathies bind to different epitopes of the 68 kDa neurofilament protein.

We describe three patients with a sensorimotor axonal polyneuropathy and an IgG M-protein that binds to a 68 kDa axonal protein identified as the low molecular weight neurofilament protein (NF-L). The immunological studies revealed that the M-proteins have different target epitopes: one is phosphorylated and the other two are nonphosphorylated. One of the nonphosphorylated epitopes is common to other intermediate filaments, such as desmin and vimentin.     

The distribution of neurofibrils coextensive with microtubules and neurofilaments in dendrites and axons of the tectum, cerebellum and pallium of the frog

Correlation of electron micrographs with the results of a variety of reduced silver stains for light microscopy indicates that neurofibrils may be stained in locations where either neurofilaments or microtubules predominate, depending upon the procedure. Reduced silver techniques following fixation with alcohol or aldehyde solutions (Cajal's block method II, methods of Nonidez, Bartelmez, DeCastro, Bodian, Guillery, and Holmes) stain neurofibrils coextensively with neurofilaments (fnf) in myelinated axons, large dendrites, and synaptic boutons but do not stain neurofibrils in most radial dendrites of the tectum or parallel fibers of the cerebellum, where numerous microtubules but few neurofilaments are present. In the latter locations neurofibrils (tnf) are stained following primary fixation in silver nitrate alone (Cajal's block method I) or alcoholic silver nitrate (method Ic), with gold toning of the sections. The methods staining tnf are highly successful in showing the distribution and orientation of the parallel fibers and radial dendrites as well as other thin axons and dendrites in the grey matter including the archipallium. Even in regions containing fnf in numerous processes, it is clear that the majority of fibers in the adult frog brain contain only tnf.     

Carbon disulfide axonopathy. Another experimental model characterized by acceleration of neurofilament transport and distinct changes of axonal size

The role of axonal transport in the development of structural changes of axons can be examined using experimental models. Two different compounds, 2,5-hexanedione (2,5-HD) and carbon disulfide (CS2), cause axonopathies characterized by the formation of neurofilaments (NF) containing enlargements in preterminal regions of central and peripheral axons. These axonopathies are excellent experimental models of the giant axonal neuropathies, a group of acquired and inherited human diseases of the central and peripheral nervous system. We previously reported that following administration of 2,5-HD, transport of NF is accelerated while number of NF and cross-sectional area are decreased in regions of the axon proximal to the enlargements. We proposed that acceleration of NF transport leads to a 'longitudinal' redistribution of NF which are decreased proximally and increased distally where they form the NF containing axonal enlargements. We have now carried out morphometric, transport and immunocytochemical studies in primary visual axons of rats exposed to CS2. NF-containing axonal enlargements were observed in optic tract and superior colliculus and they increased in number in a proximodistal direction. There was no detectable axonal degeneration and the cross-sectional area of axons proximal to the enlargements was decreased. Transport of NF was markedly accelerated. Immunostaining showed that all 3 NF subunits and phosphorylated epitopes of the 200-kDa NF subunit were present in the NF-containing axonal enlargements. All these findings were similar to those previously observed in the 2,5-HD axonopathy.(ABSTRACT TRUNCATED AT 250 WORDS)     

Lack of association between two restriction fragment length polymorphisms in the genes for the light and heavy neurofilament proteins and Alzheimer's disease

The etiology of Alzheimer disease (AD) remains unknown. The hypothesis of genetic factors playing a role in the causation of the disease, at least in its familial form, has been borne out by results showing linkage in several early-onset AD families to a locus on the proximal part of the long arm of chromosome 21. Linkage was not detected in several other families using the same markers. The metabolism of neurofilaments is perturbed in AD, as indicated by the presence of neurofilament epitopes in neurofibrillary tangles, as well as by the severe reduction of the expression of the gene for the light neurofilament subunit in AD brain. To detect a possible anomaly that might relate to the disease, we have searched for an association between the genes for the light subunit and the heavy subunit of the neurofilament triplet, and AD. Genotypes for restriction fragment length polymorphisms (RFLP) at each of the two loci were determined for an AD group and a control group. Allelic frequencies at a TaqI-defined RFLP for the gene for the light neurofilament subunit were 0.70 for the 3.7 kb allele and 0.30 for the 2.9 kb allele. HincII detected an RFLP for the heavy neurofilament subunit gene with frequencies of 0.31 for the 18.0 kb allele and 0.69 for the 6.8 kb allele. Frequencies were found to be similar in the two groups for both light and heavy neurofilament subunit loci. Although it cannot be excluded that mutations at other sites of the neurofilament genes are relevant to AD, the data reported here do not support an association between these genes and the disease.     

Mice with the deleted neurofilament of low-molecular-weight (Nefl) gene: 1. Effects on regional brain metabolism

Neuronal intermediate filaments consist of the NFL subunit linked with NFM and NFH, and their alterations have been proposed as a pathogenesic cause in motor neuron diseases. Depletion of the Nefl gene in mice mimicks the reduced NFL mRNA levels seen in amyotrophic lateral sclerosis and causes perikaryal accumulation of neurofilament proteins and axonal hypotrophy in motoneurons. NFL -/- mice were evaluated for regional brain metabolism by means of quantitative histochemical estimation of cytochrome oxidase (COx) activity. The NFL null mice displayed enzymatic activity alterations in numerous hindbrain regions, mainly the cerebellum, connected regions of the brainstem (red nucleus, vestibular nuclei, and reticular formation), and cranial nerve nuclei. All of the affected regions presented elevated COx activity, except for the Purkinje cells of the cerebellum and the magnocellular red nucleus, where enzymatic activity was lower. NFL-disrupted mice displayed functional alterations in brainstem sensorimotor regions affected in amyotrophic lateral sclerosis.     

The high and middle molecular weight neurofilament subunits regulate the association of neurofilaments with kinesin: inhibition by phosphorylation of the high molecular weight subunit

Kinesin participates in axonal transport of neurofilaments (NFs), but the mode by which they attach to kinesin is unclear. We compared the association of NFs with kinesin in mice expressing or lacking NF-H or NF-M. In normal and M-/- mice, the leading edge of metabolically labeled NF subunits was selectively co-precipitated with kinesin. By contrast, the entire wave of radiolabeled subunits co-precipitated with kinesin in H-/- mice. Similar bulk levels of NFs co-precipitated with kinesin from normal and H-/- mice, but reduced levels co-precipitated from M-/- mice. These data suggest that both NF-H and NF-M regulate the association of NFs with kinesin. They further indicate that phosphorylation of NF-H dissociates NFs from kinesin and provides a mechanism by which NF-H phosphorylation can contribute to the slowing of NF axonal transport.     

Conditioned enhancement of antibody production is disrupted by insular cortex and amygdala but not hippocampal lesions.

Pavlovian conditioning procedures can be used to activate the immune system. A reliable conditioned increase of antibody production can be obtained in rats that have previously received a gustative or odor stimulus as the conditioned stimulus paired with an antigen, by exposing the animals to the conditioned stimulus alone. We showed evidence that an excitotoxic lesion bilaterally applied into the insular cortex or the amygdala, but not into the dorsal hippocampus, impaired the acquisition of both odor and gustatory conditioned immune enhancement. We found no effects of lesions on normal antibody production. These results suggest that the amygdala and the insular cortex are involved in the neural-immune interactions that mediate conditioned immunity.     

Two novel kinases phosphorylate tau and the KSP site of heavy neurofilament subunits in high stoichiometric ratios.

We have identified, purified, and characterized two neurofilament/tau kinases from bovine brain, PK36 and PK40, with apparent Mr of 36,000 and 40,000 and with novel biochemical properties. A specially designed immunoassay for phosphorylated epitopes in neurofilament (NF) proteins was used in the early stages of the purification. Neither kinase is closely associated with the cytoskeleton. Both kinases phosphorylate bovine intermediate (NF-M) and heavy (NF-H) NF subunits and also bovine tau at the expected KSP sequences, though other sites cannot be ruled out. In human paired helical filaments, tau, phosphorylated at these same KSP sites, is a major characterized constituent. Neither kinase is activated by the usual second messengers. Tau and the above NF subunits are phosphorylated in high stoichiometric ratios. In the intermediate NF subunit, all the expected sites appear to be phosphorylated, but in the heavy NF subunit only 7 out of the greater than 40 expected sites can be phosphorylated by our kinases. We demonstrate that both kinases can induce considerable shifts of apparent Mr with SDS-PAGE for tau and, for the first time in vitro, also for the intermediate NF subunit. Interestingly, PK36 and particularly PK40 are strongly inhibited by an excess of free ATP. We propose that during normal aging, and in Alzheimer's disease, age-related mitochondrial dysfunction would reduce ATP levels, which in turn might release the neurofilament/tau kinase from inhibition with consequent paired helical filament formation.     

A crustacean neuronal cytoskeletal protein with characteristics of neurofilaments and microtubule-associated proteins.

The purpose of this study was to characterize further a unique protein that is a component of the cytoskeleton of crayfish neurons. This protein, referred to as P600, is unique because it is unusually large (Mr greater than 600 kD), and because it has characteristics in common with both mammalian microtubule-associated proteins and neurofilaments. Immunohistochemical techniques have shown that P600 colocalizes with microtubules and is a component of the fibrous side-arms that extend from microtubules (Weaver and Viancour, Brain Res. 544:49, 1991). We have developed a method for obtaining purified P600 by using gel filtration techniques. When viewed by negative staining electron microscopy, P600 obtained by that method produced 11 nm-wide beaded filaments. The number of filaments was strictly related to the P600 concentration in a column fraction. A small amount of P600 consistently copurified with taxol-stabilized microtubules. The proportion copurifying with microtubules was increased by using apyrase to deplete ATP, or by using a nonhydrolyzable ATP analogue to compete with ATP. Immunogold labeling localized P600 near the ends of a subset of the fibrous side-arms extending from endogenous axonal microtubules. Several polyclonal antibodies against mammalian microtubule-associated proteins were tested for P600 labeling on immunoblots, and positive labeling was obtained with an antiserum directed against a region of microtubule-associated protein 1B that has microtubule binding activity. Epitope homology between P600, mammalian microtubule-associated protein 1B, and the mammalian mid-molecular weight neurofilament subunit is discussed in the context of possible evolutionary relationships among these cytoskeletal proteins.     

Mice with the deleted neurofilament of low molecular weight (Nefl) gene: 2. Effects on motor functions and spatial orientation

Mice with a null mutation of the Nefl gene were compared with normal controls in tests of motor activity, equilibrium, and spatial orientation. Despite a normal capacity to ambulate, NFL -/- mice had fewer rears in an open field, crossed fewer segments on stationary beams, and fell more frequently when suspended on a horizontal bar. In addition, the distance swum before reaching the escape platform was greater in NFL -/- mice than in controls during acquisition of place learning in the Morris water maze at the start of training. The motor impairments were linearly correlated with increased cytochrome oxidase activity seen in cerebellum and brainstem. These results indicate that, as early as 6 months, depletion of the NFL protein is sufficient to cause mild sensorimotor dysfunctions and spatial deficits, but without overt signs of paresis.     

Interaction of cerebellar mutant genes. II. Mice doubly affected by 'reeler' and 'weaver' conditions.

An an extension of a study of the mode of ineraction of mutant genes that affect motor activities and cerebellar cytoarchitectonics, mice doubly affected by both the 'reeler' and 'weaver' conditions were produced. The cerebellum of the double mutant showed both reeler and weaver characteristics. Anomalies present in both mutants were greatly accentuated in the double mutant. In addition to the paucity of fissures and general cerebellar disorganization observed in reeler and the extreme scarcity of granule cells seen in weaver, double mutants showed an additional decrease in the cerebellar size and the molecular layer, and a further loss of external granule cells. These observations were interpreted as indicating that the effects of the reeler and weaver genes upon altering the cytoarchitectonics of the cerebellum were additive.     

Dscam is associated with axonal and dendritic features of neuronal cells.

Dscam, a novel cell-adhesion molecule belonging to the Ig-superfamily mediates homophilic intercellular adhesion and is expressed abundantly in the nervous system during development. To gain better understanding on the role of Dscam in neuronal differentiation, we raised an antibody and characterized its protein product. Anti-Dscam antibody detected an approximately 200-kDa protein band in human and mouse brain lysates. Immunohistochemical studies showed that during embryonic development of mice, mouse Dscam is expressed throughout the neuronal tissues and also in nonneuronal tissues such as lung, liver, and limb buds. In adult brain Dscam expression is predominant in the cerebellum, hippocampus, and olfactory bulb. Immunofluorescence double labeling of hippocampal and cerebellar primary cultures revealed that Dscam is associated with axonal and dendritic processes. In view of its cellular localization and spatiotemporal expression pattern, we suggest that Dscam is involved in cell-cell interactions during axonal-dendritic development, and maintenance of functional neuronal networks.