Dynamic regulation of middle neurofilament RNA pools during optic nerve regeneration.

Stereotypical changes in neurofilament subunit expression are highly correlated with the regenerative success of lower vertebrate CNS axons. The phylogenetically conserved binding of ribonucleoproteins to the 3'-untranslated region of the middle neurofilament subunit (NF-M) mRNA suggests that post-transcriptional mechanisms play an important role in the control of NF-M expression. To assess their contribution to the regulated changes in NF-M expression that occur during Xenopus laevis optic axon regeneration, we followed changes in intracellular NF-M RNA pools. Within 3 days after axotomy, when NF-M mRNA levels decrease in the injured retinal ganglion cells, heterogenous nuclear RNA levels increased more than 15-fold, but did so in both the operated and the contralateral unoperated eyes as compared with the eyes of surgically naive frogs. Increased nuclear RNA levels persisted throughout regeneration but never correlated directly with changes in mRNA expression, indicating that such changes most likely arose from alterations in nuclear-cytoplasmic RNA export and turnover. The early phase of optic nerve regeneration also exhibited an increase in the efficiency of translation of NF-M mRNA relative to surgically naive animals. This increase was only transient in unoperated control eye, but persisted through the peak of regeneration in the operated eye. Thus, post-transcriptional control of NF-M expression plays a significant role in regulating the cytoskeletal composition of injured neurons. These findings indicate that changes in protein expression during successful regeneration of CNS axons involve a complex interplay of transcriptional and translational regulation that is controlled by the operation of functional neuronal pathways. These findings also raise the additional possibility that factors regulating post-transcriptional changes in cytoskeletal gene expression may be as important as transcription factors for the successful regeneration of CNS axons.

Loss of neurofilaments alters axonal growth dynamics.

The highly regulated expression of neurofilament (NF) proteins during axon outgrowth suggests that NFs are important for axon development, but their contribution to axon growth is unclear. Previous experiments in Xenopus laevis embryos demonstrated that antibody-induced disruption of NFs stunts axonal growth but left unresolved how the loss of NFs affects the dynamics of axon growth. In the current study, dissociated cultures were made from the spinal cords of embryos injected at the two-cell stage with an antibody to the middle molecular mass NF protein (NF-M), and time-lapse videomicroscopy was used to study early neurite outgrowth in descendants of both the injected and uninjected blastomeres. The injected antibody altered the growth dynamics primarily in long neurites (>85 microm). These neurites were initiated just as early and terminated growth no sooner than did normal ones. Rather, they spent relatively smaller fractions of time actively extending than normal. When growth occurred, it did so at the same velocity. In very young neurites, which have NFs made exclusively of peripherin, NFs were unaffected, but in the shaft of older neurites, which have NFs that contain NF-M, NFs were disrupted. Thus growth was affected only after NFs were disrupted. In contrast, the distributions of alpha-tubulin and mitochondria were unaffected; thus organelles were still transported into neurites. However, mitochondrial staining was brighter in descendants of injected blastomeres, suggesting a greater demand for energy. Together, these results suggest a model in which intra-axonal NFs facilitate elongation of long axons by making it more efficient.

Differential expression and localization of neuronal intermediate filament proteins within newly developing neurites in dissociated cultures of Xenopus laevis embryonic spinal cord.

The molecular subunit composition of neurofilaments (NFs) progressively changes during axon development. In developing Xenopus laevis spinal cord, peripherin emerges at the earliest stages of neurite outgrowth. NF-M and XNIF (an alpha-internexin-like protein) appear later, as axons continue to elongate, and NF-L is expressed after axons contact muscle. Because NFs are the most abundant component of the vertebrate axonal cytoskeleton, we must understand why these changes occur before we can fully comprehend how the cytoskeleton regulates axon growth and morphology. Knowing where these proteins are localized within developing neurites and how their expression changes with cell contact is essential for this understanding. Thus, we examined by immunofluorescence the expression and localization of these NF subunits within dissociated cultures of newly differentiating spinal cord neurons. In young neurites, peripherin was most abundant in distal neuritic segments, especially near branch points and extending into the central domain of the growth cone. In contrast, XNIF and NF-M were usually either absent from very young neurites or exhibited a proximal to distal gradient of decreasing intensity. In older neurites, XNIF and NF-M expression increased, whereas that of peripherin declined. All three of these proteins became more evenly distributed along the neurites, with some branches staining more intensely than others. At 24 h, NF-L appeared, and in 48-h cultures, its expression, along with that of NF-M, was greater in neurites contacting muscle cells, arguing that the upregulation of these two subunits is dependent on contact with target cells. Moreover, this contact had no effect on XNIF or peripherin expression. Our findings are consistent with a model in which peripherin plays an important structural role in growth cones, XNIF and NF-M help consolidate the intermediate filament cytoskeleton beginning in the proximal neurite, and increased levels of NF-L and NF-M help further solidify the cytoskeleton of axons that successfully reach their targets.

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.

Xenopus laevis peripherin (XIF3) is expressed in radial glia and proliferating neural epithelial cells as well as in neurons.

Neuronal intermediate filament (nIF) proteins form the most abundant component of the axonal cytoskeleton. Thus, understanding their function and the regulation of their expression is essential for comprehending how axonal structure is regulated. Although most vertebrate nIF proteins are classified as type IV intermediate filament (IF) proteins, additional nIF proteins exist in frogs (Xenopus laevis), cyprinid fishes, and mammals (called XIF3, plasticin, and peripherin, respectively) that are classified as type III. Expression of a type III nIF protein is correlated strongly with the earliest phases of axonal outgrowth in fishes but less so in mammals. To understand better how the correlation between type III nIF protein expression and early phases of axonal outgrowth has changed during evolution, the authors examined XIF3 expression in Xenopus laevis. In Xenopus, the association between XIF3 expression and early axonal outgrowth was especially strong. For example, during early axonal development, XIF3 expression preceded and was more abundant and widespread than that of any of the type IV nIF proteins. As axons matured, neuronal expression of XIF3 gradually became more restricted while that of type IV nIF proteins increased. These results support the idea that type III nIF proteins play a special role during early phases of axonal outgrowth. In addition to finding XIF3 in neurons, the authors also unexpectedly found it in regions of the central nervous system that contain proliferating cells and radial glia. As a framework for interpreting variations in nIF expression in different vertebrate species, the authors built phylogenetic trees to clarify relationships among vertebrate nIF proteins. These trees supported the classification of XIF3, plasticin, and peripherin as orthologs (products of the same genetic locus, evolving separately only since the species lineages diverged). Thus, XIF3, plasticin, and peripherin probably should be referred to as Xenopus, fish, and mammalian peripherin, respectively. This finding argues that differences in expression of these three proteins in frogs, fishes, and mammals are the result of regulatory changes to the peripherin ancestral gene along each lineage. The expression of a peripherin ortholog in Xenopus glia may represent either an adaptation that arose since the divergence of Xenopus from mammals or, alternatively, a feature retained from an ancestral IF protein that was expressed originally both in neurons and in glia.

Cloning and characterization of AASPs: novel axon-associated SH3 binding-like proteins.

Two cDNAs encoding closely related proteins were isolated from a crayfish nervous system lambdagtl0 cDNA library with a rat synapsin Ia cDNA probe. These proteins were expressed exclusively in neurons, were highly enriched in axons of the crayfish, and contained multiple, overlapping, putative Src homology 3 (SH3) binding sites. In concert with other proteins containing Src homology domains, SH3 binding proteins are thought to mediate protein-protein interactions in receptor signaling processes and with the cytoskeleton. We have named these proteins axon-associated SH3 binding-like proteins (AASPs). Except for these SH3 binding regions, which are also found in synapsins, AASPs were unlike any proteins in the database. AASPs were differentially expressed among motoneuron populations in crayfish and were found in growing axons and growth cones in culture. Affinity purified polyclonal antibodies to AASP-168 recognized immunoreactive proteins in rat and Xenopus, suggesting that AASPs may be conserved across species. Although the cellular function of AASPs is unclear at this time, they appear to be novel members of a neuron-specific SH3 binding protein family, which includes the synapsins.

Microinjection of mRNA encoding rat synapsin Ia alters synaptic physiology in identified motoneurons of the crayfish, Procambarus clarkii.

Studies of identified neurons have made important contributions to our understanding of cellular neurophysiology. We have developed a technique for modifying gene expression in identified motoneurons of the crayfish Procambarus clarkii in the isolated nervous system as well as in the intact animal through the injection of exogenously synthesized RNAs. mRNA suitable for injection was transcribed in vitro from cDNA templates cloned into a plasmid, pSEM. Initially, mRNAs encoding green fluorescent protein (GFP) and beta-galactosidase were injected into the soma of the motor giant neuron (MoG) to determine whether these mRNAs could be successfully translated into protein. Both proteins were expressed. Measurements of GFP fluorescence increase indicated that GFP mRNA was stable and translated into protein for at least 3 days postinjection. We then examined the effects of expression of GFP, AASP-168 (an endogenous crayfish axonal protein), and rat synapsin Ia on MoG synaptic physiology. The mRNA injection procedure did not appear to directly influence synaptic physiology based on the results of the AASP-168 and GFP injections. Injection of mRNA encoding rat synapsin Ia resulted in a significant increase in peak excitatory postsynaptic potential (EPSP) amplitude during repetitive stimulation. These data are consistent with previous studies that have shown that synapsin deficiency reduces synaptic vesicle numbers. The translation of mRNAs with diverse functions and species of origin suggests that this approach will prove useful for studying the function of a wide variety of endogenous and exogenous genes in identified neurons.

Xefiltin, a Xenopus laevis neuronal intermediate filament protein, is expressed in actively growing optic axons during development and regeneration.

Neurofilaments are an important structural component of the axonal cytoskeleton and are made of neuronal intermediate filament (nIF) proteins. During axonal development, neurofilaments undergo progressive changes in molecular composition. In mammals, for example, highly phosphorylated forms of the middle- and high-molecular-weight neurofilament proteins (NF-M and NF-H, respectively) are characteristic of mature axons, whereas nIF proteins such as alpha-internexin are typical of young axons. Such changes have been proposed to help growing axons accommodate varying demands for plasticity and stability by modulating the structure of the axonal cytoskeleton. Xefiltin is a recently discovered nIF protein of the frog Xenopus laevis, whose nervous system has a large capacity for regeneration and plasticity. By amino acid identity, xefiltin is closely related to two other nIF proteins, alpha-internexin and gefiltin. alpha-Internexin is found principally in embryonic axons of the mammalian brain, and gefiltin is expressed primarily in goldfish retinal ganglion cells and has been associated with the ability of the goldfish optic nerve to regenerate. Like gefiltin in goldfish, xefiltin in Xenopus is the most abundantly expressed nIF protein of mature retinal ganglion cells. In the present study, we used immunocytochemistry to study the distribution of xefiltin during optic nerve development and regeneration. During development, xefiltin was found in optic axons at stage 35/36, before they reach the tectum at stage 37/38. Similarly, after an orbital crush injury, xefiltin first reemerged in optic axons after the front of regeneration reached the optic chiasm, but before it reached the tectum. Thus, during both development and regeneration, xefiltin was present within actively growing optic axons. In addition, aberrantly projecting retinoretinal axons expressed less xefiltin than those entering the optic tract, suggesting that xefiltin expression is influenced by interactions between regenerating axons and cells encountered along the visual pathway. These results support the idea that changes in xefiltin expression, along with those of other nIF proteins, modulate the structure and stability of actively growing optic axons and that this stability is under the control of the pathway which growing axons follow.

Sequence and expression patterns of two forms of the middle molecular weight neurofilament protein (NF-M) of Xenopus laevis.

The middle molecular weight neurofilament protein (NF-M) is relevant to our understanding of vertebrate neurofilaments in growing axons, both because it exists in all vertebrates and because it undergoes characteristic changes in its phosphorylation state during axonal development. Indeed, all vertebrate neurofilament proteins are believed to have originated by gene duplication from an ancestral, NF-M-like protein. The role of NF-M in axonal development has been studied extensively in the frog, Xenopus laevis, through the use of monoclonal antibodies. To acquire a better understanding of the relationship of X. laevis NF-M to that of other vertebrates and to obtain additional reagents to study and perturb neurofilaments in developing axons, we isolated cDNA clones from the nervous system. These clones encoded two forms of NF-M, which exhibited 93% amino acid identity overall and 94%, 96% and 90% identity over their head, rod, and tail domains, respectively. Synonymous nucleotide substitution rates between the two forms tied their origin to an ancestral duplication of the Xenopus genome, which occurred approximately 30 million years ago. Non-synonymous substitution rates indicated that the tail domain is evolving more rapidly than the rod domain. Both forms shared structural features in common with other vertebrate NF-Ms but had only a single example of the KSP phosphorylation motif that is repeated multiple times in the NF-Ms of bird, goldfish and mammal. In post-metamorphic frogs, the NF-M(1) transcript was consistently expressed at higher levels than that of NF-M(2), although their anatomical patterns of expression were qualitatively similar. During development, however, only NF-M(2) was detectable in retinal ganglion cells through stage 42. We speculate that the differences observed between these two forms may represent early stages of protein diversification akin to what occurred after the gene duplications that gave rise to other vertebrate neurofilament proteins.

Xefiltin, a new low molecular weight neuronal intermediate filament protein of Xenopus laevis, shares sequence features with goldfish gefiltin and mammalian alpha-internexin and differs in expression from XNIF and NF-L.

The nervous system of the postmetamorphic frog Xenopus laevis, like that of other amphibians, shows continued growth and a high capacity for regeneration, especially in its visual system. This characteristic has been attributed, in part, to the retention in adults of traits that in mammals are limited to embryos. In mammals, the progressive maturation of neurons is marked by successive changes in neuronal intermediate filament (nIF) subunit composition. For example, in mammalian forebrain, newly differentiating neurons first express the low molecular weight nIF protein alpha-internexin. As neurons mature, alpha-internexin expression declines, and expression of the low molecular weight neurofilament triplet protein (NF-L) increases. Thus, a systematic examination of the expression of low molecular weight nIF proteins in the postmetamorphic frog might reveal whether the nIF subunit composition of its neurons more closely resembles that of embryonic as opposed to adult mammals. Previously, X. laevis has been shown to express both NF-L and XNIF, a novel low molecular weight nIF protein that most closely resembles mammalian alpha-internexin. We have now discovered a new, low molecular weight nIF protein with even higher homology to alpha-internexin. We named this protein xefiltin, because it shared highest sequence identity with gefiltin, an alpha-internexin-like nIF protein from the goldfish visual system. In situ hybridization with probes to xefiltin, XNIF and NF-L showed that transcripts of all three were expressed widely throughout the post-metamorphic frog nervous system, but with distinctly different patterns of expression. For example, xefiltin was the most abundantly expressed of the three in retinal ganglion cells and in neurons of the habenular nucleus and telencephalon, whereas XNIF and NF-L were found at higher levels than xefiltin in peripheral sensory ganglia and in structures caudal to the mesencephalon. In general, the combined distributions of xefiltin and XNIF paralleled the distribution of alpha-internexin in mammalian embryos. Thus, we speculate that the persistence of alpha-internexin-like nIF proteins in the amphibian nervous system may be important for its continued potential for growth and plasticity.

Myosin light chain kinase: expression in neurons and upregulation during axon regeneration.

Myosin light-chain kinase (MLCK) regulates actin-myosin II interactions in nonskeletal muscle cells, and the use of specific pharmacological inhibitors has implicated MLCK in retinal growth cone motility and neurite outgrowth. To further establish the existence and functions of MLCK in neurons, we isolated cDNAs encoding two forms of goldfish MLCK that were differentially expressed in the brain and gut and we sequenced the form most abundantly expressed in the brain (GFMLCK1). In situ hybridization with a cRNA probe specific to GFMLCK1 revealed widespread expression in CNS neurons, including tectal periventricular neurons and cerebellar and medullary neurons. After optic nerve crush, expression was markedly increased in the retinal ganglion cells. Expression peaked during the phase of axonal outgrowth, which, when taken together with our previous pharmacological studies, further supports a role for MLCK in growth cone motility.

Effects of intermediate filament disruption on the early development of the peripheral nervous system of Xenopus laevis.

The principal function of intermediate filaments is to strengthen cells. Their developmentally regulated, tissue-specific patterns of expression further suggest that they modulate cellular structural properties during development. To explore the role of intermediate filaments in development, we injected RNA encoding a truncated form of the Xenopus laevis middle-molecular-weight neurofilament protein (NF-M) into embryonic frog blastomeres at the 2-cell stage. A similar truncated form of mammalian NF-M disrupts neurofilaments (Type IV) and vimentin (Type III) intermediate filaments in transfected fibroblasts. In cultures made from dissociated neural tubes and their adjacent myotomes, the resultant protein disrupted both desmin filaments in muscle cells and neurofilaments in neurons during the first day of culture, which corresponds to stage 35/36 in the intact embryo. We next examined the effects of this truncated neurofilament protein on development of the nervous system. The greatest effects were seen on development of cranial and primary motor nerves, which were severely stunted as late as stage 37/38. In addition to these effects, ectopic neurons also appeared immediately beneath the epidermis along the flank of tadpoles expressing the truncated neurofilament protein. Whereas the former effects on peripheral nerve development were nearly identical to effects obtained with injected neurofilament antibodies, the ectopic neurons were novel, suggesting they resulted from the disruption of intermediate filaments other than the neurofilaments. These experiments thus implicate intermediate filaments in several functions important for normal neural development.

Neurofilaments help maintain normal morphologies and support elongation of neurites in Xenopus laevis cultured embryonic spinal cord neurons.

Neurofilament number and subunit composition, which are highly regulated during development, have been proposed to help regulate axonal diameter and stability. From experiments on dissociated cell cultures of Xenopus laevis embryonic spinal cord, we have obtained direct evidence that neurofilaments help maintain the structural integrity of newly developing axons. An anti-neurofilament monoclonal antibody specific for Xenopus NF-M and the cell lineage tracer, lysinated FITC-dextran, were coinjected into a single blastomere of 2-cell stage embryos. Within neurons descended from the injected blastomere, this antibody specifically confined neurofilaments to the cell body for the first two days of culture, as assayed by immunocytochemical staining with antiserum against the low molecular weight neurofilament protein XNIF. Although whole IgGs and Fab fragments both affected neurofilament distribution, the whole IgGs were more effective. For the first 9 hr of culture, neurites containing anti-NF-M developed normally. By 21 hr, they were shorter than those of sibling control neurons within the same dish, and many became morphologically abnormal. Defects included large variations in diameter, poorly defined separations between the growth cone and neurite, and more collateral branching. Despite these abnormal features, neurons containing anti-NF-M had normal distributions of alpha-tubulin immunoreactivity and phalloidin-stained F-actin. These latter observations argued that defects resulted from the absence of neurofilaments rather than from interference of the movement of other structural materials essential for axonal growth. These results support the hypothesis that neurons use neurofilaments to help maintain the characteristic shapes of axons against the increasing structural demands placed upon the elongating process.

The Xenopus laevis homologue to the neuronal cyclin-dependent kinase (cdk5) is expressed in embryos by gastrulation.

Phosphorylation of the neuronal cytoskeletal proteins NF-H, NF-M and tau is important for normal axonal development, and is involved in axonal injury and neurodegenerative diseases. In mammalian neurons, one kinase that phosphorylates these axonal cytoskeletal proteins is cyclin-dependent kinase 5 (cdk5). Cdk5 is a member of the family of cyclin-dependent kinases (cdks), whose other family members regulate mitosis. Unlike the other cdks, cdk5 is abundant in differentiated neurons. Embryos of the clawed frog Xenopus laevis have proved useful for studying other cyclin-dependent kinases, neurofilament proteins and tau during development. As a first step in studying the role of cdk5 and its effects on neurofilaments during Xenopus neural development, four cDNA clones were isolated by screening a frog brain cDNA library at lowered stringency with a cDNA probe to rat cdk5. The frog cdk5 clones encoded a protein of 292 amino acids that was 97% identical to rat cdk5. In situ hybridization demonstrated that the Xenopus cdk5 transcript, like that of mammals, was expressed in differentiated post-mitotic neurons. The high degree of sequence homology and shared neuronal expression suggests that the role of cdk5 in neurons is highly conserved between mammals and amphibians. Northern blot analysis indicated that during Xenopus development, cdk5 mRNA was first expressed between the midblastula transition and gastrulation, which both occur long before neuronal differentiation. These stages mark the transition from synchronous to asynchronous cell division and are the earliest stages of zygotic gene expression. This early expression of Xenopus cdk5 mRNA implies a role for cdk5 during embryogenesis that is separate from its role as an axonal cytoskeletal protein kinase. These observations provide the foundation for exploiting X. laevis embryos to study the role of cdk5 both in the early stages of axonal differentiation and also in early embryogenesis.

The optic tract and tectal ablation influence the composition of neurofilaments in regenerating optic axons of Xenopus laevis.

Neurofilaments have been proposed to regulate axonal stability and diameter through changes in number and subunit composition. We have found that pathway and target innervation directly influence the molecular composition of neurofilaments within regenerating optic axons of Xenopus laevis. Immunocytochemistry was used to examine neurofilaments within two abnormal visual pathways. The first was an aberrant, transient retinoretinal projection, which formed when some axons entered the contralateral optic nerve at the chiasm. The second was formed by regenerating axons deprived of their normal targets by surgical ablation of both optic tecta. Distal to an orbital nerve crush, the neurofilament proteins NF-L, NF-M, NF-H, and XNIF disappear from degenerating fibers. In normally regenerating axons, these neurofilament proteins emerge in a progression reminiscent of development. In the aberrant retinoretinal projection, levels of XNIF, NF-L, and -M remained lower than in normally regenerating axons, whereas NF-H and a phosphorylated form of NF-M were undetectable for at least 35 d after nerve crush. Normally, these two latter forms reappear between 15 and 21 d after surgery. Thus, this transient, incorrect axonal projection expressed neurofilaments in a very different pattern from correctly regenerating axons. In tecta-ablated frogs, staining of phosphorylation independent epitopes of XNIF, NF-L, and -M increased normally after axons entered the tract, but that of NF-H and phosphorylated NF-M remained low for at least 42 d after axotomy. Thus, separate parts of the visual pathway influence the complexity of neurofilaments.

Maturation of neurites in mixed cultures of spinal cord neurons and muscle cells from Xenopus laevis embryos followed with antibodies to neurofilament proteins.

Dissociated cell cultures of Xenopus laevis embryonic spinal cord have proved useful for studying the differentiation of neuronal ionic channels and membrane properties and for examining the dynamics of microtubules in developing neurons. To examine their usefulness for studying neurofilaments in developing neurites, we prepared similar cultures from stage 22 embryos. Between 3 and 55 h after plating, these cultures were fixed and immunostained with antibodies directed against various epitopes of neurofilament proteins from X. laevis. These antibodies were specific for nonphosphorylated epitopes of the two low molecular weight Xenopus neurofilament proteins (Xenopus NF-L and the Xenopus neuronal intermediate filament protein, XNIF), both phosphorylated and nonphosphorylated epitopes of the Xenopus middle molecular weight neurofilament protein (NF-M), and a nonphosphorylated epitope of the Xenopus high molecular weight neurofilament protein (NF-H). The emergence of these neurofilament proteins in culture was compared to the time course previously reported for them in Xenopus spinal cord neurons in situ. To facilitate the comparison of times in culture to developmental stages, the age of cultured neurons was converted to an equivalent Nieuwkoop and Faber normal stage using data presented here on the effect of changing temperature on developmental rates of X. laevis. With the exception of the nonphosphorylated epitope of NF-H, which is indicative of the most mature axons found in situ, the emergence of the other neurofilament protein antibody epitopes closely paralleled that previously reported for these antibodies in situ. Thus, with respect to XNIF, NF-M, and NF-L, the neurites of cultured neurons were typical of young, embryonic Xenopus laevis spinal cord axons. This system should prove useful for studying both the function of these neurofilament proteins during the early stages of axonal development and the dynamics of their transport.

The return of phosphorylated and nonphosphorylated epitopes of neurofilament proteins to the regenerating optic nerve of Xenopus laevis.

Neurofilament proteins of mammalian axotomized peripheral axons, which regenerate effectively, resemble those of embryonic axons. However, injured centrally projecting mammalian axons, which fail to regenerate, have very different neurofilament compositions than during development. If changes in neurofilament composition after injury reflect the ability of axotomized neurons to regenerate effectively, then the neurofilaments of centrally projecting axons that can regenerate should more closely resemble those of developing axons. In this study, the neurofilament compositions of injured optic axons of the frog, Xenopus laevis, were examined, since these axons can regenerate a fully functional projection. Antibodies to phosphorylated and nonphosphorylated forms of neurofilament proteins that had been used previously to study the neurofilament composition of newly developing X. laevis optic axons were used in immunocytochemical studies to examine the return of neurofilaments to the optic nerve after an intraorbital nerve crush. Intraocularly injected wheat germ agglutinin conjugated to horseradish peroxidase was used to label the regenerating axons independently of their neurofilaments. Neurofilament immunoreactivities disappeared rapidly from crushed axons during the first week after surgery. By nine days after surgery, antibodies to nonphosphorylated forms of middle (NF-M) and low molecular weight (NF-L) neurofilament proteins and the Xenopus neuronal intermediate filament protein (XNIF) began to stain the nerve just beyond the lesion. By this time, however, growing axonal terminals had reached the optic chiasm. Antibodies to phosphorylated epitopes of NF-M began to stain axons at 15 days, just as growing axons began to arrive at the optic tectum. Nonphosphorylated high molecular weight neurofilament protein (NF-H) began to appear in axons between 18 and 21 days after surgery. Thus, the reappearance of neurofilaments during optic axon regeneration resembled the general pattern seen during development. The chief difference between development and regeneration was that neurofilament epitopes took longer to emerge during regeneration. One possibility is that cues encountered along the optic pathway influence the neurofilament composition of retinal ganglion cell axons. Then, the greater distances travelled by regenerating axons could account for the longer time taken for their neurofilament compositions to mature.

Identification and developmental expression of a novel low molecular weight neuronal intermediate filament protein expressed in Xenopus laevis.

Xenopus laevis is a valuable model system for the study of vertebrate neuroembryogenesis. However, very few well-characterized nervous system-specific molecular markers are available for studies in this organism. We screened a X. laevis adult brain cDNA library using a cDNA probe for mouse low molecular weight neurofilament protein (NF-L) in order to identify neuron-specific intermediate filament proteins. Clones for two distinct neuron-specific intermediate filament proteins were isolated and sequenced. One of these encoded for a Xenopus NF-L (XNF-L) and the other for a novel neuron-specific Xenopus intermediate filament protein (XNIF) that was present earlier and more abundantly than XNF-L during development. XNIF contained a central rod domain with multiple sequence features characteristic of IF proteins. The XNF-L was very similar to mouse NF-L, with a 77% sequence identity in the rod domain and the presence of a polyglutamic acid region in the tail domain, characteristic of type IV neurofilament proteins. In contrast, XNIF showed only 60% identity to mouse NF-L in the rod domain and lacked the glutamic acid-rich sequence in the tail domain. XNIF also had a very low (approximately 38%) sequence identity in the head and tail domains as compared to NF-L and other neurofilament proteins (45% identity to the head domain of alpha-internexin). In the adult frog, XNIF mRNA is detected by Northern blots only within the nervous system and by in situ hybridization histochemistry exclusively in neurons, particularly in the medullary reticular system and spinal cord. Antisera raised against the unique tail region of XNIF detected a single distinct 60 kDa band in Western blots of nervous system cytoskeletal preparations, and this XNIF immunoreactivity was concentrated in axons in the PNS and in small perikarya in the dorsal root ganglion. In contrast, NF-L immunoreactivity was principally in the large perikarya in the dorsal root ganglion. In development, XNIF mRNA appears more abundant than XNF-L mRNA in all premetamorphic stages examined. XNIF mRNA is first detectable at stage 24 (26 hr), whereas stable expression of XNF-L is at stage 35/36 (50 hr). XNIF immunoreactivity is detectable within the cement gland, within many neuronal cell bodies and axon tracts within the developing nervous system, and within all cellular layers of the developing retina. The availability of these two distinct neuron-specific intermediate filament proteins, with different temporal and spatial expression patterns, should provide new markers as well as targets for functional perturbation in the developing X. laevis nervous system.

Squid low molecular weight neurofilament proteins are a novel class of neurofilament protein. A nuclear lamin-like core and multiple distinct proteins formed by alternative RNA processing.

The primary structure of the major 60-kDa squid low molecular mass neurofilament protein (NF60) and a related 70-kDa neurofilament protein have been determined from cDNA clones isolated from a squid brain cDNA library. Structural analysis suggests that the squid NF60 and NF70 neurofilament genes and proteins are remarkably distinct from vertebrate neuronal intermediate filaments characterized previously. Both proteins are encoded on mRNAs generated by alternative RNA processing of the primary transcript of a single gene. Among the known intermediate filament proteins, NF60 and NF70 neurofilament proteins show highest similarity to an epithelial intermediate filament protein from Helix pomatia, a gastropod mollusk, and are less similar to vertebrate neurofilaments. The length of the alpha-helical rod domain in the NF60 and NF70 proteins was reminiscent of the vertebrate nuclear lamins, 6 heptads longer than is found in all known vertebrate cytoplasmic intermediate filaments, in particular the vertebrate neurofilaments. These distinct structural properties suggest that the vertebrate and invertebrate low molecular weight neurofilaments evolved independently from primordial intermediate filament proteins.

Inhibition of axonal development after injection of neurofilament antibodies into a Xenopus laevis embryo.

The ability to target specific cytoskeletal components in axons for disruption within intact developing embryos would provide a valuable tool for studying neuronal development. Neurofilaments are an attractive target for such an approach, because they are neuron specific and are expressed late in embryogenesis principally beginning during axon outgrowth. No pharmacological agents are currently available that disrupt neurofilaments without also affecting general development. One approach that has been used successfully to affect proteins in vivo is to inject specific antibodies into living cells. We employed this approach in Xenopus laevis embryos by injecting two antibodies directed against the middle molecular weight neurofilament protein (NF-M) into a single blastomere of a two-cell stage embryo. Injected antibodies could be detected for as long as 3.5 days in cells descended from the injected blastomere. Only cell bodies of neurons descended from anti-NF-M-injected blastomeres contained abnormal accumulations of intermediate filament proteins, and peripheral nerve development was unilaterally retarded in these neurofilament antibody-injected tadpoles. Such accumulations and peripheral nerve defects were not seen in neurons derived from uninjected blastomeres or from blastomeres injected with control antibodies. These data demonstrate the usefulness of specific antibodies to perturb neuronal development in intact frog embryos and, in addition, suggest a role for neurofilaments in axon elongation.