Reduced microtubule-nucleation activity of tau after dephosphorylation

Based on video-enhanced differential interference contrast (DIC) microscopy, we developed a small-scale method which is capable of measuring both the lengths and the number densities of microtubules (MTs) assembled in vitro. With this method, effect of dephosphorylation on the activity of bovine brain tau protein to promote the assembly of tubulin at physiological concentration (15 microM) was quantitatively analyzed. The MT number density was selectively reduced when tau isolated directly in the presence of phosphatase inhibitors (N-tau) was dephosphorylated in vitro (DP-tau), without significant changes in the mean MT length or the binding affinity toward preformed MTs. Tau obtained from brain MTs (MT-tau) also exhibited lower nucleation activity in spite of its high MT-binding affinity. The results indicate that nucleation, elongation and MT-binding are distinct aspects of tau function which are differentially affected by the phosphorylation state of tau.

Growth cone collapse and inhibition of neurite growth by Botulinum neurotoxin C1: a t-SNARE is involved in axonal growth

The growth cone is responsible for axonal growth, where membrane expansion is most likely to occur. Several recent reports have suggested that presynaptic proteins are involved in this process; however, the molecular mechanism details are unclear. We suggest that by cleaving a presynaptic protein syntaxin, which is essential in targeting synaptic vesicles as a target SNAP receptor (t-SNARE), neurotoxin C1 of Clostridium botulinum causes growth cone collapse and inhibits axonal growth. Video-enhanced microscopic studies showed (a) that neurotoxin C1 selectively blocked the activity of the central domain (the vesicle-rich region) at the initial stage, but not the lamellipodia in the growth cone; and (b) that large vacuole formation occurred probably through the fusion of smaller vesicles from the central domain to the most distal segments of the neurite. The total surface area of the accumulated vacuoles could explain the membrane expansion of normal neurite growth. The gradual disappearance of the surface labeling by FITC-WGA on the normal growth cone, suggesting membrane addition, was inhibited by neurotoxin C1. The experiments using the peptides derived from syntaxin, essential for interaction with VAMP or alpha-SNAP, supported the results using neurotoxin C1. Our results demonstrate that syntaxin is involved in axonal growth and indicate that syntaxin may participate directly in the membrane expansion that occurs in the central domain of the growth cone, probably through association with VAMP and SNAPs, in a SNARE-like way.

Immunohistochemical study of matrix metalloproteinase-3 and tissue inhibitor of metalloproteinase-1 human intervertebral discs

STUDY DESIGN

Immunohistologic staining of human intervertebral discs collected at the time of surgery (100 intervertebral discs from 80 patients) and 10 discs collected from 7 cadavers within 12 hours of death was performed using antimatrix metalloproteinase-3 monoclonal antibody and antitissue inhibitor of metalloproteinase-1 monoclonal antibody.

OBJECTIVES

To examine the relationship between matrix destruction and staining for matrix metalloproteinase-3 and tissue inhibitor of metalloproteinase-1 in intervertebral disc degeneration.

SUMMARY OF BACKGROUND DATA

Matrix metalloproteinase-3, which decomposes aggregating proteoglycans, has attracted research attention as a substance contributing to matrix destruction in the articular cartilage and intervertebral disc. However, except for a few in vitro studies, the relationship between matrix destruction of the intervertebral disc and matrix metalloproteinase-3 has been little studied.

METHODS

Immunohistologic staining was performed to examine the relationship between matrix metalloproteinase-3 and tissue inhibitor of metalloproteinase-1 in the intervertebral disc, and the relationship of these two agents to magnetic resonance imaging, radiographic, and surgical findings.

RESULTS

Those cases testing positive for matrix metalloproteinase-3 and negative for tissue inhibitor of metalloproteinase-1 accounted for most of the surgical specimens. The matrix metalloproteinase-3-positive cell ratio was significantly correlated with the magnetic resonance imaging grade of intervertebral disc degeneration, and the matrix metalloproteinase-3-positive cell ratio observed in prolapsed lumbar intervertebral discs was significantly higher than that in nonprolapsed discs. In cervical intervertebral discs, the matrix metalloproteinase-3-positive cell ratio and staining of cartilaginous endplate were correlated with the size of osteophyte formation.

CONCLUSIONS

These findings suggested that intervertebral disc degeneration is caused by disturbance in the equilibrium of matrix metalloproteinase-3 and tissue inhibitor of metalloproteinase-1, and that matrix metalloproteinase-3 contributes to degeneration of the cartilaginous endplate.

Preparation of tau from the peripheral nerve: presence of insoluble low molecular weight tau with high phosphorylation

Purely axonal tau protein of the peripheral nervous system (PNS) obtained from adult rat ventral roots was composed of both high (HMW) and low molecular weight (LMW) isoforms. While the PNS-specific HMW isoform (110 kDa) was soluble, 60-70% of the LMW isoforms with apparent molecular weights of 67 kDa, 62 kDa and 58 kDa was insoluble. When analyzed by two-dimensional electrophoresis, these axonal LMW isoforms corresponded to the most acidic species among the large number of isoforms found in brain microtubule-associated tau. Immunoreactivities towards phosphorylation-dependent antibody tau-1 and the two anti-phosphopeptide antibodies (PP1 and PP2) indicate that PNS axonal tau is highly phosphorylated at Ser190, Ser193, and Ser387, which are the sites shown to be phosphorylated in fetal brain tau and tau comprising the paired helical filaments of Alzheimer's disease.

Phosphorylation and transport of neurofilament proteins in the rat spinal ganglion

Neurofilament proteins (NFs) in rat spinal ganglia were labeled with [32P]orthophosphate injected into ganglia and analyzed by two-dimensional autoradiography and immunoblotting. Three polypeptides of NF were labeled irrespective of the extent of phosphorylation. Most of the labeled NFs were transported from cell bodies to proximal axons within 24 h. A major fraction of low phosphorylated NF-H changed to high phosphorylated form in intraganglionic nerve fibers and peripheral nerves adjacent to spinal ganglia. A small fraction of low phosphorylated NF-H appeared earlier than the high phosphorylated form in adjacent peripheral nerves, suggesting that newly synthesized NF-H in cell bodies migrate a long distance before they are extensively phosphorylated and assembled into the cytoskeleton in proximal axons.

Two stages in neurite formation distinguished by differences in tubulin metabolism

Changes in tubulin solubility during neurite formation were studied biochemically using rat dorsal root ganglion neurons in culture. When fractionated with Ca(2+)-containing buffer at low temperature, a considerable proportion of total cellular tubulin was recovered in the insoluble fraction. We designated this cold/Ca(2+)-insoluble tubulin (InsT) and distinguished it from cold/Ca(2+)-soluble tubulin (SoIT). From the relative amount of InsT, neurite formation was found to proceed through two distinct stages. The first 6 days after plating (stage 1) in which the proportion of InsT increased dramatically (from 5 to 60%) coincided with neurite outgrowth. In the following period (stage 2), a constant level of InsT was maintained, whereas neurite maturation took place. Pulse-labeling experiments further revealed that the two stages differed significantly in terms of tubulin metabolism. High rates of synthesis as well as conversion from SoIT to InsT were observed in stage 1, whereas stage 2 was characterized by a decrease in both of these rates and an increase in the rate of degradation. The results show for the first time the coordinated changes in tubulin metabolism that underlie the process of neurite formation.

Decreased synaptic density in aged brains and its prevention by rearing under enriched environment as revealed by synaptophysin contents

Changes in synaptic density in various brain regions were assessed among different age groups of rats maintained in ordinary small cages, as determined by synaptophysin assay. The synaptophysin content in hippocampus decreases as early as in the adult stage. The most remarkable decrement occurs in occipital cortex. In other regions, synaptophysin contents decrease in senescence to 60-77% of the respective peak values during young and adult stages. The other rat group reared under enriched environment in a large cage until 30 months of age was examined for synaptic density, and was revealed to maintain the similar levels as in young, or even higher levels in frontal, temporal, entorhinal cortices and hippocampus. These results indicate that the synaptic density in cerebrum decreases in senescence and this decrease can be prevented by rearing under enriched environment.

Early effects of beta,beta'-iminodipropionitrile on tubulin solubility and neurofilament phosphorylation in the axon

To elucidate the role of neurofilaments in microtubule stabilization in the axon, we studied the effects of beta,beta'-iminodipropionitrile (IDPN) on the solubility and transport of tubulin as well as neurofilament phosphorylation in the motor fibers of the rat sciatic nerve. IDPN is known to impair the axonal transport of neurofilaments, causing accumulation of neurofilaments in the proximal axon and segregation of neurofilaments to the peripheral axoplasm throughout the nerve. Administration of IDPN at various intervals after radioactive labeling of the spinal cord with L-[35S]methionine revealed that transport inhibition occurred all along the nerve within 1-2 days. Transport of cold-insoluble tubulin, which accounts for 50% of axonal tubulin, was also affected. A significant increase in the proportion of cold-soluble tubulin was observed, reaching a maximum at 3 days after IDPN treatment and returning to the control level in the following weeks. Preceding this change in tubulin solubility, a transient decrease in the phosphorylation level of the 200-kDa neurofilament protein was detected in the ventral root using phosphorylation-dependent antibodies. These early changes agreed in timing with the onset of segregation and transport inhibition, suggesting that interaction between neurofilaments and microtubules possibly regulated by phosphorylation plays a significant role in microtubule stabilization.

Axonal transport of actin and actin-binding proteins in the rat sciatic nerve

Actin is one of the major cytoskeletal proteins carried in slow axonal transport. Since more than 50% of actin in the axon was recovered in the high-speed supernatant, we looked for G-actin-binding proteins in slow axonal transport. Two weeks after injection of L-[35S]methionine into the rat spinal cord (L3-L5), labeled proteins in the sciatic nerve were extracted and those with potential abilities to interact with G-actin were detected by two independent methods: (A) DNAase I affinity chromatography and (B) blot overlay with biotinylated actin. By method (A), a 68 kDa Ca(2+)-dependent binding protein and a 45 kDa Ca(2+)-independent binding protein were detected. The 68 kDa protein was also a major protein binding to actin in method (B). The 68 kDa protein was identified with the Ca(2+)-dependent phospholipid binding protein annexin VI by two-dimensional electrophoresis and Western blotting. As annexin VI is a component of slow axonal transport, it does not seem to be bound to membranous organelles in the axon. Our results suggest that annexin VI may play a role in the control of actin assembly and membrane-microfilament interaction.

Characteristics of gangliosides including O-acetylated species in growth cone membranes at several developmental stages in rat forebrain

Growth cones, the motile tips of extending neuronal processes, are involved in accurate synaptogenesis. To study the developmental changes in ganglioside composition including O-acetylated gangliosides in growth cones, we analyzed the gangliosides in growth cone membranes (GCM) prepared from rat forebrains at different developmental stages. At several stages, GCM contained significantly larger amounts of gangliosides than the other membrane subfractions. The ganglioside content of GCM increased in amount with development. Moreover, in GCM, the relative amount of GD3 gradually decreased, and that of GD1a dramatically increased. There were significant differences in the composition of ganglioside species between GCM and the perinuclear plasma membrane subfraction (NM); most importantly, GCM had a higher ratio of GD1a to GM3 plus GD3 than NM. There were three different O-acetylated gangliosides in GCM: O-acetyl-GD3, O-acetyl-GT1b, and O-acetyl-GQ1b. The molar ratio of O-acetyl-GD3 decreased in GCM at later stages (5% of the total gangliosides at embryonic day 17, to 1% at postnatal day 5). However, those of the other two O-acetylated gangliosides were almost constant (1-2% of the total). Our results show that there are significant differences in ganglioside content and composition between the membrane subfraction of growth cones and the perinuclear portion. This suggests that several species of gangliosides, including O-acetyl-GD3, play a role in growth cone function.

Impairment of cytoskeletal protein transport due to aging or beta,beta'-iminodipropionitrile intoxication in the rat sciatic nerve

Three major age-related changes in cytoskeletal organization and metabolism in the axon were observed by comparing slow axonal transport in the sciatic nerves of rats aged 7-80 weeks: (a) a progressive decrease in the rate of slow axonal transport, (b) a tight association of cold-insoluble tubulin with the neurofilament (NF) proteins and (c) an accelerated proteolysis of the severely retarded proteins, especially NF proteins. These changes were reproduced to a large extent in the young animal by intoxication with beta,beta'-iminodipropionitrile (IDPN). As IDPN is known to impair the axonal transport of NF proteins and cause segregation of NFs from microtubules, the results indicate that NF-microtubule interaction is one of the major factors regulating the axonal cytoskeleton. The importance of the balance between transport rate and degradation rate in the maintenance of the normal axonal cytoskeleton is stressed especially in the aged animal.

Effect of an aromatase inhibitor in human follicular fluid on DNA synthesis of granulosa cells, theca cells, and follicles

An aromatase inhibitor was identified in human follicular fluid. We sought to examine the effects of this inhibitor on granulosa cells, theca cells, a mixture of granulosa and theca cells, and follicles. Granulosa cells, theca cells, the mixture of granulosa and theca cells, and follicles were incubated with [3H]-thymidine and aromatase inhibitor at 37 degrees C for 40 h in Ham F-10 medium. The radioactivities of acid-soluble fractions were counted. Aromatase inhibitor markedly inhibited the DNA synthesis of granulosa cells and follicles, but it did not inhibit the mixture of granulosa and theca cells. This suggested that aromatase inhibitor was a factor in the follicle paracrine system and acted mainly on granulosa cells.

Changes of fast axonal transport by taxol injected subepineurally into the rat sciatic nerve

In contrast to the complete and long-lasting inhibition of tubulin transport, taxol has no effect on fast axonal transport examined immediately after its sub-epineural application to rat sciatic nerve. However, a significant accumulation of rapidly migrating radioactivity appears at the site proximal to the injection when examined a few weeks after treatment, probably due to mechanical obstruction caused by abnormal aggregation of a huge number of intra-axonal microtubules. It also decreases slightly in amount within a few weeks post-treatment, which may be due to reduction of the number of axons caused by degeneration.

Actin-binding proteins in the growth cone particles (GCP) from fetal rat brain: a 44 kDa actin-binding protein is enriched in the fetal GCP fraction

Neuronal growth cones, the motile tips of growing neurites, are thought to play a significant role in nerve growth. To study the role of actin in their motility, we examined actin-binding proteins in growth cone particles (GCP) isolated from fetal rat brain, using a blot-overlay method with biotinylated actin. Among the more than ten species of actin-binding proteins in the GCP, a 44 kDa protein was found specifically in growth cones and was enriched in the cytoskeletal and the membrane skeletal subfractions from the GCP. This protein binds to actin in a Ca(2+)- and Mg(2+)-dependent manner, and ATP enhances its binding to actin. The protein was predominantly present in the fetal GCP, but it is expressed at a much lower level in the neonatal GCP and not detected in adult synaptosomes. The protein also bound to a deoxyribonuclease I column and was eluted by EGTA-containing buffer. The 44 kDa protein appears to be a novel actin-binding protein, since none of the known actin-binding proteins exhibit this combination of properties. Our results suggest that the protein may be involved with the early stages of neurite extension.

Organization and slow axonal transport of cytoskeletal proteins under normal and regenerating conditions

The organization of the axonal cytoskeleton was investigated by analyzing the solubility and transport profile of the major cytoskeletal proteins in motor axons of the rat sciatic nerve under normal and regenerating conditions. When extracted with the Triton-containing buffer at low temperature, 50% of tubulin and 30% of actin were recovered in the insoluble form resistant to further depolymerizing treatments. Most of this cold-insoluble form was transported in slow component a (SCa), the slower of the two subcomponents of slow axonal transport, whereas the cold-soluble form showed a biphasic distribution between SCa and SCb (slow component b). Changes in slow transport during regeneration were studied by injuring the nerve either prior to (experiment I) or after (experiment II) radioactive labeling. In experiment I where the transport of proteins synthesized in response to injury was examined, selective acceleration of SCb was detected together with an increase in the relative proportion of this component. In experiment II where the response of the preexisting cytoskeleton was examined, a shift from SCa to SCb of the cold-soluble form was observed. The differential distribution and response of the two forms of tubulin and actin suggest that the cold-soluble form may be more directly involved in axonal transport.

Biochemical characterization of nerve growth cones isolated from both fetal and neonatal rat forebrains: the growth cone particle fraction mainly consists of axonal growth cones in both stages

Nerve growth cones are responsible for the exact pathway finding, and for the establishment of neurocytoarchitecture. To elucidate the developmental changes of biochemical characteristics of nerve growth cones, growth cone particle (GCP) fractions were isolated biochemically from embryonal day 17 (E17) rat forebrain and from postnatal day 5 (P5). There were no significant differences in protein phosphorylation pattern in a Ca(2+)-dependent manner between E17-GCP fraction and that of P5. As for the membrane lipid composition, molar ratios of cholesterol to total phospholipids were well conserved during these ages. The immunoreactivity to anti-synaptophysin monoclonal antibody as a marker of mature synaptic elements could not be detected either in E17-GCP or P5-GCP fractions. To exclude the possibility of the contamination of dendritic elements, RNA contents and immunoreactivity to anti-high molecular weight microtubule-associated protein 2 (MAP2) monoclonal antibody were examined. RNA contents of the GCP fractions were extremely low compared to those of other subcellular fractions both in E17 and P5. No immunoreactivities to anti-MAP2 antibody were observed in either GCP fraction. Our results suggest that the GCP fractions, isolated from forebrains of E17 to P5 rat, are free from the contamination of the synaptic elements, and that the GCP fractions are mainly composed of axonal growth cones.

Maturation and aging of the axonal cytoskeleton: biochemical analysis of transported tubulin

Changes in solubility and axonal transport of tubulin during maturation and aging have been investigated using sciatic motor fibers of rats at 4, 7, 14, 30, and 80 weeks of age. One to six weeks after injection of L-[35S]methionine into the spinal cord, labeled cytoskeletal proteins in consecutive segments of the sciatic nerve and the ventral roots were fractionated into soluble and insoluble forms by extraction in 1% Triton at low temperature. In 4-week-old rats, the two forms of tubulin were transported coordinately in a single wave with the average rate of 2 mm/day. At 7 weeks of age, two components in tubulin transport were observed to develop, possibly reflecting the maturation of the axonal cytoskeleton. The slower main component (1.5 mm/day) contained most of the insoluble form together with the neurofilament proteins and the faster component (3 mm/day) was enriched in the soluble form. Though significantly different in composition, the two components correspond to slow component a (SCa) and slow component b (SCb) originally defined in the optic system. A progressive decrease in transport rates of both SCa and SCb was observed with rats at 14, 30, and 80 weeks of age. In addition, there was a large decrease in the proportion of insoluble tubulin during the course of transport in animals older than 30 weeks. This loss of the insoluble form seems to be accounted for partly by the proteolytic degradation of the severely retarded SCa proteins. Changes in axonal transport of tubulin may thus reflect age-related changes in dynamics and turnover of the axonal cytoskeleton.

Tyrosine phosphorylation and immunodetection of vinculin in growth cone particle (GCP) fraction and in GCP-cytoskeletal subfractions

The growth cone, the motile tip of developing neuronal processes, is considered responsible for the exact guidance of axons and synaptogenesis. High activity of tyrosine kinases in growth cones may contribute to the functions of growth cones. Our previous work revealed that vinculin is one of the endogenous substrates for intrinsic tyrosine kinases in the growth cone particle (GCP) fraction isolated from fetal rat brain. In the present study, we examined tyrosine phosphorylation and immunoblot analysis of vinculin in various fractions from fetal rat brains and adult synaptosomal fraction. Tyrosine phosphorylation of vinculin in the GCP fraction was more prominent than in any other fraction from fetal brain or synaptosomes from adult. Compared to other fractions, however, the enrichment of vinculin in the GCP fraction was not observed. Tyrosine phosphorylation of vinculin in the fraction was inhibited by genistein, a specific tyrosine kinase inhibitor. Although vinculin was also phosphorylated by protein kinase C in the GCP fraction, it incorporated a much smaller amount of 32P than MARCKS protein or GAP-43. The cytoskeletal subfraction from the GCP fraction contained a considerable amount of vinculin and it was one of the major substrates for tyrosine kinases in the GCP cytoskeleton. The membrane skeleton from the GCP fraction contained a low amount of vinculin but showed high kinase activity that phosphorylated vinculin. Taken together, our results suggest that tyrosine phosphorylation of vinculin contributes to the cytoskeletal organization of growth cones.

Subtypes of protein kinase C in isolated nerve growth cones: only type II is associated with the membrane skeleton from growth cones

The growth cone particle (GCP) fraction was isolated from fetal and neonatal rat brains and the distribution of protein kinase C subtypes in the fraction was examined by using subtype-specific antibodies. The main subtype in the GCP fraction from fetal forebrain was type II, and type III was also present, but not type I. The pattern was not altered from embryonic day 17 to postnatal day 5. The membrane skeleton subfraction from the GCP fraction contained type II, but far less amount of type III. Our results suggest that type II and type III may be closely related to the functions of growth cones but that they appear to be associated with distinct signal transduction processes.

Changes in organization and axonal transport of cytoskeletal proteins during regeneration

Changes in solubility and transport rate of cytoskeletal proteins during regeneration were studied in the motor fibers of the rat sciatic nerve. Nerves were injured by freezing at the midthigh level either 1-2 weeks before (experiment I) or 1 week after radioactive labeling of the spinal cord with L-[35S]methionine (experiment II). Labeled proteins in 6-mm consecutive segments of the nerve 2 weeks after labeling were analyzed following fractionation into soluble and insoluble populations with 1% Triton at 4 degrees C. When axonal transport of newly synthesized cytoskeleton was examined in the regenerating nerve in experiment I, a new faster component enriched in soluble tubulin and actin was observed that was not present in the control nerve. The rate of the slower main component containing most of the insoluble tubulin and actin together with neurofilament proteins was not affected. A smaller but significant peak of radioactivity enriched in soluble tubulin and actin was also detected ahead of the main peak when the response of the preexisting cytoskeleton was examined in experiment II. It is thus concluded that during regeneration changes in the organization take place in both the newly synthesized and the preexisting axonal cytoskeleton, resulting in a selective acceleration in rate of transport of soluble tubulin and actin.

Two 68-kDa proteins in slow axonal transport belong to the 70-kDa heat shock protein family and the annexin family

The major 68-kDa protein found selectively in the faster of the two subcomponents of slow axonal transport [group IV or slow component b (SCb)] in the rat sciatic nerve has been characterized. It was found to contain two distinct classes of proteins, S1 and S2, both of which have isoelectric points of 5.7, but differ in their solubility in the presence of calcium. The S1 protein, which contributes up to 70% of the 68-kDa component, was soluble in the presence or absence of calcium, whereas the S2 protein was bound to the cytoskeleton in a calcium-dependent manner. Further characterization of the two proteins by peptide mapping and immunological methods revealed that the S1 protein belonged to a family of proteins related to the 70-kDa heat shock protein, whereas the S2 protein was identical to 68-kDa calelectrin (annexin VI). Selective occurrence in SCb of these proteins with potential abilities to regulate protein-protein or protein-membrane interactions suggests that they may play important roles in the control of cytoskeletal organization in the axon, because SCb contains mainly cytoskeletal proteins in a more dynamic form compared with the slowest rate component, slow component a, which is enriched in the stably polymerized form of these proteins.

Muscarinic acetylcholine receptors are expressed and enriched in growth cone membranes isolated from fetal and neonatal rat forebrain: pharmacological demonstration and characterization

Nerve growth cones, the motile tips of growing neurites, are closely related to the exact pathway finding, and their roles for synaptogenesis have been proposed to be modified by some neurotransmitters. In the present study, to clarify the expression and the ontogeny of muscarinic acetylcholine receptors in growth cones, growth cone membranes from fetal and neonatal rat forebrain were isolated, and muscarinic receptors in growth cone membrane were pharmacologically characterized, by using the [3H]quinuclidinyl benzilate as a labeled ligand. The specific binding sites for [3H]quinuclidinyl benzilate had already been detected in growth cone membrane on embryonic day (E)17 (Bmax = 557 fmol/mg protein: KD = 19.7 pM) and gradually increased in amount without significant changes in the KD values from E17 to postnatal day (P)5. [3H]Quinuclidinyl benzilate binding sites in growth cone membrane were several times higher than that in the P2-fraction-derived membranes, and in perinuclear membranes. Competitive inhibition studies showed that the proportion of high-affinity sites for pirenzepine (M1-subtype) to total [3H]quinuclidinyl benzilate binding sites in growth cone membrane was significantly lower than that in adult synaptic plasma membranes. In contrast, the proportion of high-affinity sites for AF-DX 116 (M2-subtype) was significantly higher than that in adult synaptic plasma membranes (E17 growth cone membrane: M1, 29.5%; M2, 56.9%; adult synaptic plasma membrane: M1, 63.6%, M2, 5.9%). Electron micrographic examination revealed that there were no significant morphological differences among growth cone particle fractions at the developmental stages which we examined, and that mature synaptic elements did not contaminate the growth cone particle fractions. Biochemical examination by electrophoresis and the phosphorylation study of the growth cone particle fractions showed that the protein composition and the phosphoprotein pattern did not change markedly during these stages. Our results suggest that muscarinic receptors were expressed and more concentrated in growth cone membrane than in other membrane portions from perinatal rat forebrain, and that they may play some role in the axonal guidance in growth cone via receptor subtype-specific signal transduction mechanisms.

Vinculin is one of the major endogenous substrates for intrinsic tyrosine kinases in neuronal growth cones isolated from fetal rat brain

Neuronal growth cones, the motile tips of growing neuronal processes, are responsible for the exact guidance of extending neurites. To elucidate the mechanisms of their biochemical signal transduction in growth cones, the growth-cone-enriched fraction was isolated biochemically from fetal rat brain and the endogenous protein phosphorylation in the fraction was analyzed under the conditions where tyrosine residues were preferentially phosphorylated. One of the major phosphoproteins was a 130-kDa slightly acidic protein which reacted with antiphosphotyrosine antibody. Its phosphoryl residues were alkali-stable. Thus, the 130-kDa protein was concluded to be susceptible to tyrosine phosphorylation. This protein was a component of cytoskeletal proteins thought to be associated indirectly with membranes. All the behavior of the 130-kDa protein was compatible with the properties of vinculin, a component of focal contacts which are responsible for the stable or motile adhesion between cells or between a cell and the substratum. Immunochemical analyses showed that the 130-kDa protein was specifically recognized by anti-vinculin antibody. Therefore, the 130-kDa protein was concluded to be vinculin. Tyrosine phosphorylation of the protein appeared to be relatively more pronounced in the growth-cone-enriched fraction than in adult synaptosomes. The results suggest that tyrosine phosphorylation of vinculin may be regulated developmentally and it may be involved in the functions of growth cones.