Multiple fates of newly synthesized neurofilament proteins: evidence for a stationary neurofilament network distributed nonuniformly along axons of retinal ganglion cell neurons

We have studied the fate of neurofilament proteins (NFPs) in mouse retinal ganglion cell (RGC) neurons from 1 to 180 d after synthesis and examined the proximal-to-distal distribution of the newly synthesized 70-, 140-, and 200-kD subunits along RGC axons relative to the distribution of neurofilaments. Improved methodology for intravitreal delivery of [3H]proline enabled us to quantitate changes in the accumulation and subsequent decline of radiolabeled NFP subunits at various postinjection intervals and, for the first time, to estimate the steady state levels of NFPs in different pools within axons. Two pools of newly synthesized triplet NFPs were distinguished based on their kinetics of disappearance from a 9-mm "axonal window" comprising the optic nerve and tract and their temporal-spatial distribution pattern along axons. The first pool disappeared exponentially between 17 and 45 d after injection with a half-life of 20 d. Its radiolabeled wavefront advanced along axons at 0.5-0.7 mm/d before reaching the distal end of the axonal window at 17 d, indicating that this loss represented the exit of neurofilament proteins composing the slowest phase of axoplasmic transport (SCa or group V) from axons. About 32% of the total pool of radiolabeled neurofilament proteins, however, remained in axons after 45 d and disappeared exponentially at a much slower rate (t 1/2 = 55 d). This second NFP pool assumed a nonuniform distribution along axons that was characterized proximally to distally by a 2.5-fold gradient of increasing radioactivity. This distribution pattern did not change between 45 and 180 d indicating that neurofilament proteins in the second pool constitute a relatively stationary structure in axons. Based on the relative radioactivities and residence time (or turnover) of each neurofilament pool in axons, we estimate that, in the steady state, more neurofilament proteins in mouse RGC axons may be stationary than are undergoing continuous slow axoplasmic transport. This conclusion was supported by biochemical analyses of total NFP content and by electron microscopic morphometric studies of neurofilament distribution along RGC axons. The 70-, 140-, and 200-kD subunits displayed a 2.5-fold proximal to distal gradient of increasing content along RGC axons. Neurofilaments were more numerous at distal axonal levels, paralleling the increased content of NFP.(ABSTRACT TRUNCATED AT 400 WORDS)     

Axonal Polypeptides Cross-Reactive with Antibodies to Neurofilament Proteins

Antibodies were prepared to mammalian CNS neurofilament proteins (NFPs) and the antibody specificities were compared using a sensitive immunoblotting method. This procedure was used to detect and characterize cross-reactive proteins and their degradation products in neurofilament preparations. NFPs were prepared by axon flotation. Rabbits were immunized with 200,000, 140,000, and 70,000 NFPs (200K, 140K, and 70K) that had been electrophoretically purified by polyacrylamide gel electrophoresis (PAGE). By immunohistofluorescence it was shown that all antisera stained similar filamentous structures in rat cerebellar neurons. By use of a horseradish peroxidase-conjugated indirect antibody procedure, however, differences were detected in the cross-reactivities of the antisera to rat NFPs, separated by PAGE and electrophoretically transferred to nitrocellulose membranes. Each antiserum exhibited strong binding to the homologous NFP and, thus, was suitable for the detection of cross-reactive polypeptides and proteolytic degradation products derived exclusively from the individual NFPs. Anti-200K, anti-140K, or anti-70K was applied to overloaded two-dimensional nitrocellulose blots of NFPs prepared by axon flotation. Each of the three sera detected a group of unique nonoverlapping polypeptides, some of which were identified as NFP degradation products. A different group of polypeptides was cross-reactive with antiserum to purified glial fibrillary acidic protein. The immunostaining of polypeptides on nitrocellulose was far more sensitive for detecting NFP degradation products than was staining polyacrylamide gels with Coomassie blue. Titers for the antisera were two to three orders of magnitude higher with the immunoblotting procedure than with immunohistologic methods. The sensitivity and the specificity of the described methods suggest their usefulness for examining proteolytic cleavage products of NFPs under a variety of conditions.     

Differential turnover of phosphate groups on neurofilament subunits in mammalian neurons in vivo

The phosphorylation and dephosphorylation of specific proteins was demonstrated directly in the intact vertebrate nervous system in vivo. By exploiting the neurons' ability to segregate a select group of cytoskeletal proteins from most other phosphorylated constituents of the cell by axoplasmic transport, we were able to examine the dynamics of phosphate turnover on neurofilament proteins in mouse retinal ganglion cell neurons simultaneously labeled with [32P]orthophosphate and [3H]proline in vivo. Three [3H]proline-labeled neurofilament protein (NFP) subunits, designated H (160-200 kDa), M (135-145 kDa), and L (68-70 kDa), entered optic axons in a mole:mole ratio similar to that of isolated axonal neurofilaments, supporting the notion that newly synthesized NFPs are transported along axons as assembled neurofilaments. NFP subunits incorporated high levels of 32P before reaching axonal sites at the level of the optic nerve. As neurofilaments were transported along axons, however, many initially incorporated [32P]phosphate groups were removed. Loss of these phosphate groups occurred to a different extent on each subunit. A minimum of 50-60 and 35-40% of the labeled phosphate groups was removed in a 5-day period from the L and M subunits, respectively. By contrast, the H subunit exhibited relatively little or no phosphate turnover during the same period. Dephosphorylation of L in axons is accompanied by a decrease in its net state of phosphorylation; changes in the phosphorylation state of H and M, however, also reflect ongoing addition of phosphates to these polypeptides during axonal transport (Nixon, R.A., Lewis, S.E., and Marotta, C.A. (1986) J. Neurosci., in press). The possibility is raised that dynamic rearrangements of phosphate topography on NFPs represent a mechanism to coordinate interactions of neurofilaments with other proteins as these elements are transported and incorporated into the stationary cytoskeleton along retinal ganglion cell axons.     

Long-term survival followed by degradation of neurofilament proteins in severed Mauthner axons of goldfish

The morphology and protein composition of intact and severed Mauthner axons (M-axons) from goldfish were examined on electron micrographs, sodium dodecyl sulfate gels, and immunoblots. Neurofilaments were the most common cytoskeletal element on electron micrographs, and neurofilament proteins (NFPs) were the most intensely silver-stained bands in M-axoplasm microdissected from control M-axons. NFPs at about 235, 145, 123, 105, 80, and 60 kD in M-axoplasm were identified with four monoclonal and three polyclonal antibodies. Similar immunoblots of samples of the M-axon myelin sheath (M-sheath) showed no reactivity to antibodies against NFPs. For up to 62 days following spinal cord severance in goldfish maintained at 15°C, the ultrastructure, protein banding pattern, and anti-NFP immunoreactivity of severed distal segments of M-axons did not change compared with control M-axons. At 62 to 81 days after severance, novel bands appeared in many silver-stained gels and anti-NFP immunoblots of distal M-axons. NFP bands completely disappeared from distal M-axon segments of some M-axons as early as 72 days after severance. However, NFP bands persisted in some distal segments for up to 81 days after severance. The degradation of NFPs occurred equally along the entire length of a distal M-axon segment, that is, there was no indication of a proximal-to-distal or distal-to-proximal sequence of NFP degradation in distal segments of severed M-axons. These biochemical data were consistent with morphological data that showed little change in the diameter or ultra-structure of severed M-axons held at 15°C for about 2 months followed by a rapid collapse of the entire distal segment at 72 to 85 days postseverance. 1994 John Wiley & Sons, Inc.     

Degradation of neurofilament proteins by purified human brain cathepsin D

Abstract: Cathepsin D (CD) was purified to homogeneity from postmortem human cerebral cortex. Incubation of CD with human neurofilament proteins (NFPs) prepared by axonal flotation led to the rapid degradation of the 200,000, 160,000, and 70,000 NFP subunits (200K, 160K, and 70K) which had been separated by one-or two-dimensional sodium dodecyl sulfate-polyacrylámide gel electrophoresis (SDS-PAGE). Degradation was appreciable at enzyme activity-to-substrate protein ratios that were two-to threefold lower than those in unfractionated homogenates from cerebral cortex. Quantitative measurements of NFPs separated by PAGE revealed that, at early stages of digestion, the 160K NFP was somewhat more rapidly degraded than the 70K subunit while the 200K NFP had an intermediate rate of degradation. At sufficiently high enzyme concentrations, all endogenous proteins in human NF preparations were susceptible to the action of CD. Human brain CD also degraded cytoskeletal proteins in NF preparations from mouse brain with a similar specificity. To identify specific NFP breakdown products, antisera against each of the major NFPs were applied to nitrocellulose electroblots of NFPs separated by two-dimensional SDS-PAGE. In addition to detecting the 200K, 160K, and 70K NFP in human NF preparations, the antisera also detected nonoverlapping groups of polypeptides resembling those in NF preparations from fresh rat brain. When human NF preparations were incubated with CD, additional polypeptides were released in specific patterns from each NFP subunit. Some of the immuno-cross-reactive fragments generated from NFPs by CD comigrated on two-dimensional gels with polypeptides present in unincubated preparations. These results demonstrate that NFPs and other cytoskel-etal proteins are substrates for CD. The physiological significance of these findings and the possible usefulness of analyzing protein degradation products for establishing the action of proteinases in vivo are discussed.     

Interactionin vitro of the neurofilament triplet proteins from porcine spinal cord with natural RNA and DNA

Neurofilaments were isolated from porcine spinal cord and separated into their subunit proteins (68 Kd NFP, 145 Kd NFP, 200 Kd NFP) by ion exchange chromatography on DEAE-cellulose in 6 M urea. The individual proteins were reacted with total rRNA from Ehrlich ascites tumor cells and the reaction products analysed by sucrose gradient centrifugation at low ionic strength and in the presence of EDTA. All three proteins interacted with rRNA with a preference for 18S rRNA. Competition experiments with native and heat-denatured calf thymus DNA showed that the affinities of the 68 Kd and 145 Kd NFPs were considerably higher for denatured DNA than for rRNA and that native DNA was only a weak competitor. The binding of the 200 Kd NFP to rRNA was unaffected by native and by denatured DNA. When denatured DNA was reacted with a mixture of the 68 Kd and 145 Kd NFPs, the two proteins interacted independently with the nucleic acid, giving rise to two different populations of deoxyribonucleoprotein particles. This segregation is the result of the cooperative interaction of the neurofilament proteins with single-stranded DNA. It could not be observed with rRNA or bacteriophage MS2 RNA. The results clearly show that the 68 Kd and 145 Kd NFPs are single-stranded RNA- and DNA-binding proteins, whereas the 200 Kd NFP seems to be only a single-stranded RNA-binding protein.     

Calcium-activated proteolysis of neurofilament proteins in goldfish Mauthner axons

We have examined the proteolytic breakdown of neurofilament proteins (NFPs) in isolated Mauthner axoplasm (M-axoplasm). Documentation of proteolytic breakdown of NFPs in M-axoplasm is important because NFPs are not degraded in distal segments of severed Mauthner axons (M-axons) maintained in vivo for up to 62 days at 20°C. By incubating M-axoplasm with 2 mM calcium in vitro, we have demonstrated that M-axoplasm contains an endogenous calcium-activated neutral protease that degrades NFPs. This calcium-activated proteolysis of M-axoplasm NFPs produced novel bands on silver-stained gels. These novel bands were presumed to be NFP breakdown products because they reacted with antibodies to the α-intermediate filament antigen (anti-IFA) on immunoblots from these gels. Incubations of M-axoplasm with 2 mM calcium plus exogenous calpain produced novel bands similar to those observed for M-axoplasm incubated with 2 mM calcium. Incubations of M-axoplasm with 2m M calcium plus calpain inhibitors did not produce these novel bands. These in vitro data indicate that M-axoplasm contains calpain that degrades NFPs and produces novel bands similar to those observed from distal segments of severed M-axons maintained in vivo longer than 62 days postseverance. Factors that affect the activity of calpain or affect the ability of calpain to degrade NFPs could account for the delayed degradation of NFPs in distal segments of severed M-axons maintained in vivo. © 1995 John Wiley & Sons, Inc.     

Intermediate filaments in nervous tissues

Intermediate filaments have been isolated from rabbit intradural spinal nerve roots by the axonal flotation method. This method was modified to avoid exposure of axons to low ionic strength medium. The purified filaments are morphologically 75-80 percent pure. The gel electrophoretogram shows four major bands migrating at 200,000, 145,000, 68,000, and 60,000 daltons, respectively. A similar preparation from rabbit brain shows four major polypeptides with mol wt of 200,000 145,000, 68,000, and 51,000 daltons. These results indicate that the neurofilament is composed of a triplet of polypepetides with mol wt of 200,000, 145,000, and 68,000 daltons. The 51,000-dalton band that appears in brain filament preparations as the major polypeptide seems to be of glial origin. The significance of the 60,000- dalton band in the nerve root filament preparation is unclear at this time. Antibodies raised against two of the triplet proteins isolated from calf brain localize by immunofluorescence to neurons in central and peripheral nerve. On the other hand, an antibody to the 51,000-dalton polypeptide gives only glial staining in the brain, and very weak peripheral nerve staining. Prolonged exposure of axons to low ionic strength medium solubilizes almost all of the triplet polypeptides, leaving behind only the 51,000- dalton component. This would indicate that the neurofilament is soluble at low ionic strength, whereas the glial filament is not. These results indicate that neurofilaments and glial filaments are composed of different polypeptides and have different solubility characteristics.     

Axonally transported proteins associated with axon growth in rabbit central and peripheral nervous systems

In an effort to determine whether the “growth state” and the “mature state” of a neuron are differentiated by different programs of gene expression, we have compared the rapidly transported (group I) proteins in growing and nongrowing axons in rabbits. We observed two polypeptides (GAP-23 and GAP-43) which were of particular interest because of their apparent association with axon growth. GAP-43 was rapidly transported in the central nervous system (CNS) (retinal ganglion cell) axons of neonatal animals, but its relative amount declined precipitously with subsequent development. It could not be reinduced by axotomy of the adult optic nerves, which do not regenerate; however, it was induced after axotomy of an adult peripheral nervous system nerve (the hypoglossal nerve, which does regenerate) which transported only very low levels of GAP-43 before axotomy. The second polypeptide, GAP-23 followed the same pattern of growth-associated transport, except that it was transported at significant levels in uninjured adult hypoglossal nerves and not further induced by axotomy. These observations are consistent with the “GAP hypothesis” that the neuronal growth state can be defined as an altered program of gene expression exemplified in part by the expression of GAP genes whose products are involved in critical growth-specific functions. When interpreted in terms of GAP hypothesis, they lead to the following conclusions: (a) the growth state can be subdivided into a “synaptogenic state” characterized by the transport of GAP-23 but not GAP-43, and an “axon elongation state” requiring both GAPs; (b) with respect to the expression of GAP genes, regeneration involves a recapitulation of a neonatal state of the neuron; and (c) the failure of mammalian CNS neurons to express the GAP genes may underly the failure of CNS axons to regenerate after axon injury.     

Characterization and Comparison of Neurofilament Proteins from Rat and Mouse CNS

Rat and mouse CNS neurofilament proteins (NFPs) were characterized and compared, in terms of electrophoretic properties on polyacrylamide gels and by peptide mapping, with one another and with other co-purifying lower-molecular-weight CNS proteins, including α and β tubulin. NFPs were partially purified by modification of the axon flotation procedure of Norton and co-workers and were demyelinated with Triton X-100. On one-dimensional SDS polyacrylamide gels the molecular weights of the triad of NFPs from both rat and mouse were approximately 200,000, 140,000, and 70,000. Prominent lower-molecular-weight proteins (63,000-16,000) as well as minor amounts of tubulin and actin were observed after gel electrophoresis. On two-dimensional gels (isoelectric focusing followed by SDS gel electrophoresis) each of the NFPs appeared to be composed of more than one component and the corresponding NFPs from rat and mouse had similar isoelectric points. Gel electrophoresis peptide mapping using Staphylococcus aureus V8 protease indicated the following: (1) the triad of NFPs of different sizes have different peptide maps; (2) α and β tubulin have nonidentical digestion products, which are dissimilar to those of the NFPs; (3) other proteins that co-purify by the axon flotation procedure also have nonidentical peptide maps; and (4) the corresponding NFPs from rat and mouse have similar peptide maps. The co-purifying proteins examined in detail (63,000–49,000) do not appear to be derived by proteolytic cleavage of NFPs and may represent other cytoskeletal constituents.     

Avian Tumor Virus Proteins and RNA in Uninfected Chicken Embryo Cells

The content of proteins P19 and P15 (mol wt 19,000 and 15,000, respectively) of avian leukovirus in various types of uninfected chicken embryos has been determined by radioimmunoassay. All chicken embryos examined, including embryos which have thus far been classified as group specific (gs) antigen negative by complement fixation tests, contained these viral proteins as well as P27 as previously reported. The embryos known as “gs antigen-positive” type contained about five times as much of these viral proteins as did the “gs antigen-negative” type. The ratio of the three viral proteins was similar for all types of embryos, suggesting that the genes for these proteins are coordinately controlled. In contrast to the relatively high levels of viral internal proteins in gs antigen-negative cells, the amounts of virus-specific RNA detectable by molecular hybridization were extremely low. The levels of helper activity, which presumably reflect the level of viral envelope glycoprotein, were also generally low or undetectable in these cells. Thus, the expression of the gene for envelope glycoprotein does not appear to be controlled coordinately with the genes for viral internal proteins.     

Antifungal Hydrolases in Pea Tissue : I. Purification and Characterization of Two Chitinases and Two beta-1,3-Glucanases Differentially Regulated during Development and in Response to Fungal Infection

Chitinase and β-1,-3-glucanase activities increased coordinately in pea (Pisum sativum L. cv “Dot”) pods during development and maturation and when immature pea pods were inoculated with compatible or incompatible strains of Fusarium solani or wounded or treated with chitosan or ethylene. Up to five major soluble, basic proteins accumulated in stressed immature pods and in maturing untreated pods. After separation of these proteins by chromatofocusing, an enzymic function could be assigned to four of them: two were chitinases and two were β-1,3-glucanases. The different molecular forms of chitinase and β-1,3-glucanase were differentially regulated. Chitinase Ch1 (mol wt 33,100) and β-1,3-glucanase G2 (mol wt 34,300) were strongly induced in immature tissue in response to the various stresses, while chitinase Ch2 (mol wt 36,200) and β-1,3-glucanase G1 (mol wt 33,500) accumulated during the course of maturation. With a simple, three-step procedure, both chitinases and both β-1,3-glucanases were purified to homogeneity from the same extract. The two chitinases were endochitinases. They differed in their pH optimum, in specific activity, in the pattern of products formed from [³H]chitin, as well as in their relative lysozyme activity. Similarly, the two β-1,3-glucanases were endoglucanases that showed differences in their pH optimum, specific activity, and pattern of products released from laminarin.     

Serotonin transporter-mediated molecular axis regulates regional retinal ganglion cell vulnerability and axon regeneration after nerve injury

Molecular insights into the selective vulnerability of retinal ganglion cells (RGCs) in optic neuropathies and after ocular trauma can lead to the development of novel therapeutic strategies aimed at preserving RGCs. However, little is known about what molecular contexts determine RGC susceptibility. In this study, we show the molecular mechanisms underlying the regional differential vulnerability of RGCs after optic nerve injury. We identified RGCs in the mouse peripheral ventrotemporal (VT) retina as the earliest population of RGCs susceptible to optic nerve injury. Mechanistically, the serotonin transporter (SERT) is upregulated on VT axons after injury. Utilizing SERT-deficient mice, loss of SERT attenuated VT RGC death and led to robust retinal axon regeneration. Integrin β3, a factor mediating SERT-induced functions in other systems, is also upregulated in RGCs and axons after injury, and loss of integrin β3 led to VT RGC protection and axon regeneration. Finally, RNA sequencing analyses revealed that loss of SERT significantly altered molecular signatures in the VT retina after optic nerve injury, including expression of the transmembrane protein, Gpnmb. GPNMB is rapidly downregulated in wild-type, but not SERT- or integrin β3-deficient VT RGCs after injury, and maintaining expression of GPNMB in RGCs via AAV2 viruses even after injury promoted VT RGC survival and axon regeneration. Taken together, our findings demonstrate that the SERT-integrin β3-GPNMB molecular axis mediates selective RGC vulnerability and axon regeneration after optic nerve injury.     

Difference in phosphorylation of neurofilament proteins in motor neurons and spinal ganglion cells

The composition of the neurofilament proteins (NFPs) in neuronal perikarya was examined by two-dimensional (2-D) gel electrophoresis of isolated perikarya of bovine spinal motor neurons. The extent of phosphorylation of the high molecular weight subunit of NFP (NFP-H) was compared between motor and sensory neuronal perikarya in spinal cord and spinal ganglion by immunocytochemistry with monoclonal antibodies (MAbs) to NFP. Of the 23 MAbs used in this study, one MAb (82E10) was specific to the highly phosphorylated component of NFP-H examined by 2-D immunoblot whereas another MAb (3A8) was specific to NFP-H irrespective of its level of phosphorylation. Immunocytochemically, 82E10 did not stain the perikarya of bovine and rabbit spinal motor neurons but 3A8 stained the perikarya in both animal species. These findings are consistent with 2-D immunoblot of neuronal perikarya of bovine motor neurons isolated in bulk. As for the spinal ganglia, 82E10 stained many, but not all, perikarya of sensory neurons of both animal species. These results indicate that the extent of phosphorylation of NFP-H in the perikarya of most spinal ganglion cells is higher than that of motor neurons. These findings suggest that the rate of phosphorylation of NFP-H in perikarya or the axonal transport of NFP from perikarya to proximal axons is uniform in spinal motor neurons but variable in spinal ganglion cells.     

Developmental changes in phosphorylation state of neurofilament proteins in the chick embryonic optic nerve

Developmental changes in the phosphorylation state of neurofilament proteins (NFPs) in the chick embryonic optic nerve were histochemically and biochemically studied using monoclonal antibody (MAb) 82E10 specific to the highly phosphorylated components of high (180K)- and middle (160K)-molecular-weight subunits of neurofilament (NF) in the chicken. Cross sections of developing embryonic optic nerve were studied by enzyme immunohistochemistry using this MAb. The staining pattern showed marked changes with the developmental stage. In 6-day embryos (E6) the entire cross section was stained, whereas in E10 only about a ventroposterior half of the cross section was stained. In E14 nearly the entire area of the cross section became unstained. Thereafter, the immunoreactivity reappeared and gradually increased, such that in E20 the entire cross section became immunopositive again. Electrophoretic and immunoblot analyses were made on optic nerves dissected out of embryos of various stages. The 82E10 immunoreactivity at the position of NF-M underwent a transient loss in E14 in parallel with the time course of histochemical change. Two-dimensional gels stained for protein further showed that the highly phosphorylated form of NF-M is transiently lost from embryonic optic nerve in E14, while the less phosphorylated form persists throughout the embryonic developmental stages. In order to understand the orderly loss of the 82E10 immunoreactivity in relation to retinotopic and chronotopic organizations of the fibers in the embryonic optic nerve, retinal injection of a fluorescent dye DiI as an anterograde tracing marker for selected fibers was utilized. An ordered arrangement of the fibers was present within the embryonic optic pathway, suggesting that the orderly loss of the 82E10 immunoreactivity in the embryonic optic nerve reflects the chronological order of the optic axons. These changes in the phosphorylation state of NFPs in the embryonic optic nerve presumably reflect dynamic changes of the neuronal cytoskeleton at certain stages during development.     

Posttranslational processing of alpha-tubulin during axoplasmic transport in CNS axons

Tubulin proteins in mouse retinal ganglion cell (RGC) neurons were analyzed to determine whether they undergo posttranslational processing during axoplasmic transport. Alpha- and beta-tubulin comprised heterogeneous proteins in the primary optic pathway (optic nerve and optic tract) when examined by two-dimensional (2D) PAGE. In addition, however, alpha-tubulin exhibited regional heterogeneity when consecutive 1.1-mm segments of the optic pathway were analyzed separately. In proximal segments, alpha-tubulin consisted of two predominant proteins separable by isoelectric point and several less abundant species. In more distal segments, these predominant proteins decreased progressively and the alpha-tubulin region of the gel was represented by less abundant multiple forms only; beta-tubulin region of the gel was represented by less abundant multiple forms only; beta- tubulin was the same in all segments. After intravitreal injection of [3H]proline to mice, radiolabeled alpha- and beta-tubulin heteroproteins were conveyed together at a rate of 0.1-0.2 mm/d in the slowest phase of axoplasmic transport. At 45 d postinjection, the distribution of radiolabeled heterogeneous forms a alpha- and beta- tubulin in consecutive segments of optic pathway resembled the distribution of unlabeled proteins by 2D PAGE, indicating that regional heterogeneity of tubulin arises during axonal transport. Peptide mapping studies demonstrated that the progressive alteration of alpha- tubulin revealed by PAGE analysis cannot be explained by contamination of the alpha-tubulin region by other proteins on gels. The results are consistent with the posttranslational processing of alpha-tubulin during axoplasmic transport. These observations, along with the accompanying report (J. Cell Biol., 1982, 94:150-158), provide additional evidence that CNS axons may be regionally specialized.     

Semaphorin 3d guides laterality of retinal ganglion cell projections in zebrafish

The optic chiasm is an important choice point at which retinal ganglion cell (RGC) axons either cross the midline to innervate the contralateral brain or turn back to innervate the ipsilateral brain. Guidance cues that regulate this decision, particularly those directing the midline crossing of contralateral axons, are still not well understood. Here we show that Sema3d, a secreted semaphorin expressed at the midline, guides the crossing of RGC axons in zebrafish. Both Sema3d knockdown and ubiquitous overexpression induced aberrant ipsilateral projections, suggesting that Sema3d normally guides axons into the contralateral optic tract. Live imaging in vivo showed that RGC growth cones responded to ubiquitous Sema3d overexpression by pausing for extended periods and increasing their exploratory behavior at the midline, suggesting that Sema3d overexpression causes the midline environment to become less favorable for RGC axon extension. Interestingly, Sema3d overexpression did not affect growth cone behaviors before the midline, suggesting that RGC axons normally respond to Sema3d only upon reaching the midline. After Sema3d knockdown, growth cones grew across the midline but then paused or repeatedly retracted, impairing their ability to leave the midline region. Our results indicate that a proper balance of Sema3d is needed at the midline for the progression of RGC axons from the chiasm midline into the contralateral optic tract.     

Slit1 and Slit2 cooperate to prevent premature midline crossing of retinal axons in the mouse visual system.

During development, retinal ganglion cell (RGC) axons either cross or avoid the midline at the optic chiasm. In Drosophila, the Slit protein regulates midline axon crossing through repulsion. To determine the role of Slit proteins in RGC axon guidance, we disrupted Slit1 and Slit2, two of three known mouse Slit genes. Mice defective in either gene alone exhibited few RGC axon guidance defects, but in double mutant mice a large additional chiasm developed anterior to the true chiasm, many retinal axons projected into the contralateral optic nerve, and some extended ectopically-dorsal and lateral to the chiasm. Our results indicate that Slit proteins repel retinal axons in vivo and cooperate to establish a corridor through which the axons are channeled, thereby helping define the site in the ventral diencephalon where the optic chiasm forms.     

Protein-chemical characterization of NF-H, the largest mammalian neurofilament component; intermediate filament-type sequences followed by a unique carboxy-terminal extension

NF-H has the highest mol. wt. of the three mammalian neurofilament components (NF-L, NF-M, NF-H). In spite of its unusually large mol. wt., estimated to be 200 K by gel electrophoresis, NF-H contains sequences which identify it as an integral intermediate filament (IF) protein in its amino-terminal region. We have isolated and partially characterized a basic, non-α-helical segment located at the amino-terminal end with properties similar to headpieces of other non-epithelial IF proteins. The highly α-helical 40-K fragment excised by chymotrypsin is now identified by the amino acid sequence of a 17-K fragment. This sequence can be unambiguously aligned with the rod region of other IF proteins and covers about half of the presumptive coiled-coil arrays. NF-H and NF-M show 45% sequence identity in this region. The extra mass of NF-H in comparison with most other IF proteins arises from a carboxy-terminal extension thought to be responsible for inter-neurofilament cross-bridges in axons. This autonomous domain has a unique amino acid composition characterized by a high content of proline, alanine and particularly of lysine and glutamic acid. The NF-H tailpiece extension also carries a large number of serine phosphates, which are not evenly distributed, but are restricted to the amino-terminal part. Having now delineated the intermediate filament-type sequences for all three neurofilament proteins it seems very likely that the three components interact via coiled-coil interactions. They all carry unique carboxy-terminal extensions which increase in length from NF-L to NF-H and seem to extend from the filament wall.