"Nuclear FGF receptor-1 and CREB binding protein: an integrative signaling module".

In this review we summarize the current understanding of a novel integrative function of Fibroblast Growth Factor Receptor-1 (FGFR1) and its partner CREB Binding Protein (CBP) acting as a nuclear regulatory complex. Nuclear FGFR1 and CBP interact with and regulate numerous genes on various chromosomes. FGFR1 dynamic oscillatory interactions with chromatin and with specific genes, underwrites gene regulation mediated by diverse developmental signals. Integrative Nuclear FGFR1 Signaling (INFS) effects the differentiation of stem cells and neural progenitor cells via the gene-controlling Feed-Forward-And-Gate mechanism. Nuclear accumulation of FGFR1 occurs in numerous cell types and disruption of INFS may play an important role in developmental disorders such as schizophrenia, and in metastatic diseases such as cancer. Enhancement of INFS may be used to coordinate the gene regulation needed to activate cell differentiation for regenerative purposes or to provide interruption of cancer stem cell proliferation.

Arginine methylation of a mitochondrial guide RNA binding protein from Trypanosoma brucei.

RBP16 is a mitochondrial Y-box protein from the parasitic protozoan Trypanosoma brucei that binds guide RNAs and ribosomal RNAs. It is comprised of an N-terminal cold-shock domain and a C-terminal domain rich in glycine and arginine residues, resembling the RGG RNA-binding motif. Arginine residues found within RGG domains are frequently asymmetrically dimethylated by a class of enzymes termed protein arginine methyltransferases (PRMTs). As Arg-93 of RBP16 exists in the context of a preferred sequence for asymmetric arginine dimethylation (G/FGGRGGG/F), we investigated whether modified arginines are present in native RBP16 by MALDI-TOF and post-source decay analyses. These analyses confirmed that Arg-93 is dimethylated. In addition, Arg-78 exists as an unmodified or as a monomethylated derivative, and Arg-85 is present in forms corresponding to the unmodified, di-, and tri-methylated state. While Arg-93 is apparently constitutively dimethylated, the methylation of Arg-78 and Arg-85 is mutually exclusive. Furthermore, whole cell extracts from procyclic form T. brucei are able to methylate bacterially expressed RBP16 (rRBP16), as well as endogenous proteins, in the presence of S-adenosyl-L-[methyl-3H]methionine. While assays of mitochondrial extracts suggest a small amount of PRMT may also be present in this subcellular compartment, the majority of trypanosome PRMT activity is extramitochondrial. We show that rRBP16 is methylated in trypanosome extracts through the action of a type I methyltransferase as well as serving as a substrate for heterologous mammalian type I PRMTs. In addition, we demonstrate the presence of type II PRMT activity in trypanosome cell extracts. These results suggest that protein arginine methylation is a common posttranslational modification in trypanosomes, and that it may regulate the function of RBP16.

Increased MAP1B expression without increased phosphorylation in manganese-treated PC12Mn cells.

Regulation of MAP1B expression and phosphorylation is thought to play an important role in neuronal development, particularly with regard to axon growth. The present work utilizes a novel PC12 cell variant [26] which exhibits many of the early morphological features of neurite outgrowth when stimulated with manganese chloride. Expression of MAP1B was determined by immunoblots and phosphorylation was assessed by metabolic radiolabeling with [32P]orthophosphate or with a phospho-specific antibody. The results indicate that MAP1B protein levels rise within 12 to 24 h, but there is no significant change in the phosphorylation of MAP1B. The latter conclusion is based on (i) experiments utilizing SMI 31, a monoclonal antibody that specifically reacts with phospho-MAP1B and (ii) assessments of both MAP1B phosphorylation and MAP1B protein within that same isloated protein band on Western blots. Thus, manganese increases MAP1B expression without affecting its relative phosphorylation. Although manganese does not cause neurite formation in the parental PC12 cell line, manganese is capable of inducing transient neurite regeneration from NGF-primed cells. These studies provide further evidence that the onset of neurite outgrowth may proceed without increased phosphorylation of MAP1B. During sustained neurite regeneration, however, NGF increases phosphate incorporation into MAP1B. Based on all of these findings, we conclude that early phases of neurite outgrowth (cell spreading and formation of short tapered extensions) do not necessarily require elevated phosphorylation of MAP1B.

Rat serum induces a differentiated phenotype in a rat parotid acinar cell line.

To establish a continuous cell line, freshly prepared rat parotid acinar cells were stably transfected with a plasmid vector containing the SV40 large T antigen. The acinar origin of these cells was confirmed by Western blotting, enzyme analysis, and morphological analysis. Transformed cells grown in 10% rat serum showed a modest reduction in cell number after 7 days and a concentration- and time-dependent increase in amylase levels approximately 16 times greater than those observed in fetal bovine serum-treated cells. Ultrastructural analysis revealed that cells grown in rat serum harbored protein-filled secretory granules localized adjacent to the endoplasmic reticulum, and punctate amylase-specific immunofluorescence distributed throughout the cytoplasm was consistent with the presence of amylase in secretory organelles. Clonal cells express tissue-specific proline-rich proteins and the four protein kinase C isozymes present in primary culture. Carbachol and isoproterenol stimulated [3H]protein secretion and isoproterenol enhanced amylase secretion from cells grown in rat serum. Moreover, norepinephrine, carbachol, and substance P produced a time- and concentration-dependent rise in cytoplasmic Ca2+. This continuous cell line of parotid acinar cells, which after treatment with rat serum retains the basic structural and functional properties of primary culture cells, will be utilized as a model system for studying long-term biological processes that regulate parotid cell function.

Nerve growth factor-specific regulation of protein methylation during neuronal differentiation of PC12 cells.

Protein methylation is a posttranslational modification that can potentially regulate signal transduction pathways in a similar manner as protein phosphorylation. The role of protein methylation in NGF signaling was examined by metabolic labeling of PC12 cell proteins with L-[methyl-3H]methionine and by in vitro labeling of cell proteins with L-[methyl-3H]S-adenosylmethionine. Effects of NGF were detected within 15 min. Methyl-labeled proteins were resolved by one and two dimensional SDS-PAGE. NGF affected the methylation of several 68-60-kD proteins (pI 5.8-6.4) and 50-kD proteins (isoelectric point pH 6.7-6.8 and 5.8-6.2). Several NGF-induced changes in methylation increased over several hours and through 4 d. Moreover, methyl labeling of several specific proteins was only detected after NGF treatment, but not in nontreated controls. The effects of NGF on protein methylation were NGF specific since they were not observed with EGF or insulin. A requirement for protein methylation for neurite outgrowth was substantiated with either of two methylation inhibitors: dihydroxycyclopentenyl adenine (DHCA) and homocysteine. DHCA, the more potent of the two, markedly inhibits protein methylation and neurite outgrowth without affecting cell growth, NGF-induced survival, cell flattening, or several protein phosphorylations that are associated with early signaling events. Removal of DHCA leads to rapid protein methylation of several proteins and concurrent neurite outgrowth. The results indicate that NGF regulates the methylation of several specific proteins and that protein methylation is involved in neurite outgrowth from PC12 cells.

Inhibition of expression of PKC-alpha by antisense mRNA is associated with diminished cell growth and inhibition of amylase secretion by AR4-2J cells.

AR4-2J pancreatoma cells were stably transfected with an expression vector containing the cDNA for PKC-alpha in the antisense orientation. Transfectants designated antisense-alpha AA1, AA2, and AA3 exhibited marked reductions in PKC-alpha expression and decrements in cell growth. The magnitude of the decrement in cell growth paralleled the reduction in PKC-alpha expression, i.e., AA3 > AA1 > AA2. The ability of dexamethasone to induce cell differentiation as assessed by a rise in cellular amylase levels was not markedly affected by the reduction in PKC-alpha expression. Unstimulated amylase release was attenuated in AA1 cells and almost completely blocked in AA2 transfectants. The AA2 transfectant cell line failed to elicit a secretory response to caerulein, and the AA1 transfectant exhibited a lack of the secondary phase of stimulated amylase secretion. These findings demonstrate that PKC-alpha is involved in the mechanisms regulating growth and secretion in AR4-2J cells, but is not necessary for the induction of amylase stores following differentiation.

Phosphorylation of type III beta-tubulin PC12 cell neurites during NGF-induced process outgrowth.

Nerve growth factor (NGF) produces both rapid and delayed cellular responses that are involved in neuronal differentiation. Neurite formation, a conspicuous delayed response, is accompanied by phosphorylation of beta-tubulin in PC12 cells. The present work provides further characterization of the phospho form of beta-tubulin in this neuronal model system with regard to isotype, cellular localization, and the circumstances that favor its formation. The results indicate that neuron-specific type III beta-tubulin (beta III-tubulin) is selectively affected during neurite formation. This phosphorylation occurs relatively late in the NGF signal transduction cascade and increases progressively with increasing duration of NGF treatment concomitant with more extensive neurite growth. The subcellular distribution of beta III-tubulin is not markedly different from that of total tubulin, but the phosphorylated protein is uniquely associated with microtubules that are calcium and cold labile. Although NGF is capable of inducing phosphorylation of beta III-tubulin, it is not necessarily sufficient. Based on experiments that employ either nonpermissive substrate conditions or microtubule-depolymerizing drugs, this phosphorylation requires neurite outgrowth. Direct measurements of the phospho form in neurites versus cell bodies by means of a microculture system indicate that phosphorylated beta III-tubulin is enriched in neurites. The enrichment of phospho-beta III-tubulin in calcium- and cold-labile polymer within neurites and its near absence in nonneurite bearing, NGF-treated cells suggests a role for this posttranslationally modified protein in the regulation of dynamic microtubules involved in neurite formation.

Activation of a calcium-calmodulin-dependent protein kinase I cascade in PC12 cells.

It has been observed that the activity of Ca2+-calmodulin (CaM)-dependent protein kinase I is enhanced up to 50-fold by its phosphorylation in vitro by a distinct CaM kinase I kinase (Lee, J. C., and Edelman, A. M. (1994) J. Biol. Chem. 269, 2158-2164). It has, however, been unclear whether this event represents an acute form of cellular regulation. We demonstrate here the phosphorylation and activation of CaM kinase I in PC12 pheochromocytoma cells in response to elevation of intracellular Ca2+. Treatment of PC12 cells with the Ca2+-ionophore, ionomycin, or with a depolarizing concentration of KCl, led to rapid, biphasic phosphorylation of CaM kinase I and to increases in CaM kinase I activity of 5.1- and 7. 3-fold, respectively. Depolarization-induced activation of CaM kinase I was reduced by approximately 80% by blockade of Ca2+ influx through L-type voltage-dependent Ca2+ channels and completely abolished by removal of extracellular Ca2+. The ability of PC12 cell CaM kinase I to be phosphorylated and activated by purified CaM kinase I kinase in vitro was markedly reduced by prior depolarization of the cells, consistent with intracellular phosphorylation and activation of CaM kinase I by CaM kinase I kinase. These results demonstrate the existence in PC12 cells of a CaM kinase I cascade, the function of which may be to sensitize cells to signal-induced elevations of intracellular Ca2+.

Epidermal growth factor induces the differential release of GP2 and amylase from AR4-2J cells.

Epidermal growth factor (EGF) stimulates secretion of glycoprotein 2 (GP2) in a time-and concentration-dependent manner from the AR4-2J pancreatoma cell line. Cell differentiation induced by dexamethasone treatment for 3 d, however, did not significantly alter either basal or EGF-stimulated GP2 release. Basal and EGF-stimulated GP2 release were similarly unaffected by caerulein, which promotes amylase secretion by a regulated route. A brief exposure to cycloheximide profoundly blocked EGF-evoked GP2 secretion. Furthermore, EGF-stimulated GP2 release was not accompanied by significant alterations in intracellular ionic calcium levels, in contrast to the stimulatory actions of caerulein. We conclude that EGF-stimulated release of GP2 occurs via a novel secretory pathway that is neither regulated nor constitutive as currently defined.

EGF-mediated phosphorylation of extracellular signal-regulated kinases in osteoblastic cells.

Epidermal growth factor (EGF) induces a rapid increase in the phosphorylation of extracellular signal-regulated kinases (ERKs) in the human osteosarcoma osteoblastic cell line G292 and in primary cultures of rat osteoblastic cells. This phosphorylation is transient and time-dependent. Maximal stimulation is attained within 1 min in G292 and within 5 min in rat osteoblastic cells. Enzymatic activity in G292 cells is also induced rapidly after EGF stimulation. Western blot analysis revealed that enhancement of the phosphorylation of ERKs in the EGF-stimulated cells is not due to an increase in ERK protein, since EGF-treatment does not lead to an increase in the absolute amount of ERKs present even after 2 days of stimulation. The pattern of expression of the ERKs observed in the two cell types differs in the apparent molecular weights observed. The most slowly migrating immunoreactive protein (approximately 45 kDa) in normal rat osteoblastic cells is ERK1, identified by an ERK1-selective antiserum. The same antiserum reacts only weakly with one of the ERK proteins (44 kDa) blotted from the human osteosarcoma cell line G292. Phorbol 12-myristate 13-acetate (PMA) is also capable of inducing ERK phosphorylation, albeit to a lasser degree. The combination of PMA and EGF does not produce a greater response than EGF alone. The role of protein kinase C (PKC) in the EGF-stimulated ERK signaling pathway was further examined by inhibition of PKC with the staurosporine analog, CGP41251, and by down-regulation of PKC via chronic treatment with PMA. Chronic PMA treatment results in a partial inhibition of the EGF-mediated phosphorylation. CGP41251 completely abolishes the increased ERK activity produced by PMA, but the effect of EGF in this regard is potentiated. We conclude that PKC and EGF act through parallel pathways to stimulate ERK phosphorylation and activity. The inhibitor studies, in addition, indicate that activation of PKC may moderate the actions of the EGF pathway via a tonic inhibitory feedback.

Identification and characterization of carboxyl ester hydrolase as a phospholipid hydrolyzing enzyme of zymogen granule membranes from rat exocrine pancreas.

Salt-washed (0.6 m NaCl) zymogen granule membranes (ZGM) of rat pancreatic acinar cells were utilized to identify and characterize membrane protein(s) responsible for phospholipase and lysophospholipase activities. Five major bands were identified in salt-washed ZGM by Coomassie Brilliant Blue. A 70-kDa protein with enzymatic activity was retained in significant quantities after several washes with 0.6 M NaCl but could be displaced from ZGM by 2 m NaCl or by 100 mg/ml heparin. By contrast, GP2, an integral membrane protein, was not displaced under these conditions. These findings suggest that the enzyme is a peripheral membrane protein of ZGM. Renaturation of ZGM proteins following electrophoresis revealed that the 70-kDa protein possessed phospholipase activity. Identification of the 70-kDa protein as a membrane-associated carboxyl ester hydrolase was based upon: (a) the use of a specific polyclonal antiserum, (b) N-terminal sequence, (c) two-dimensional gel analysis, (d) enzymatic characterization, and (e) co-localization to an area of a non-reducing gel containing significant phospholipase activity. Other ZGM proteins, namely GP2 and GP3, could not be demonstrated to possess phospholipase activity under the experimental conditions employed. Our finding that carboxyl ester hydrolase from ZGM exhibits PLA1 and lysophospholipase activities represents the first identification and characterization of a protein responsible for phospholipase activity in secretory granule membranes.

Differential effect of NGF and EGF on ERK in neuronally differentiated PC12 cells.

The purpose of this study was to examine ERK enzymatic activity after neuronal differentiation and to determine if the intracellular enzyme continues to be responsive to changes in extracellular NGF. The results demonstrate that long-term NGF maintains ERK activity above normal resting levels, but that it is also greatly reduced from that achieved rapidly after NGF stimulation. Withdrawal of NGF reduces ERK activity further. Re-stimulation of the enzyme by readdition of NGF after NGF withdrawal results in a 10-fold increase in activity. Withdrawal and readdition of EGF is without such a marked effect. The ability of ERK to respond to changes in NGF after neuronal differentiation indicates that this enzyme may serve important functions in addition to the induction of the neuronal phenotype.

Characterization of a PC12 cell sub-clone (PC12-C41) with enhanced neurite outgrowth capacity: implications for a modulatory role of high molecular weight tau in neuritogenesis.

To address the means by which diversity of neuronal morphology is generated, we have isolated and characterized naturally occurring variants of rat PC12 pheochromocytoma cells that exhibit altered neurite outgrowth properties in response to nerve growth factor (NGF). We describe here a PC12 cell sub-clone, designated PC12-clone 41 (PC12-C41), that displays significant increases in neurite abundance and stability when compared with the parental line. This difference does not appear to be due to an altered sensitivity or responsiveness to NGF or to a more rapid rate of neurite extension. Because of the role of the cytoskeleton in neuritogenesis, we examined a panel of the major cytoskeletal proteins (MAP 1.2/1B, beta-tubulin, chartins, peripherin, and high and low molecular weight (HMW and LMW) taus) whose levels and/or extent of phosphorylation are regulated by NGF in PC12 cultures. Although most cytoskeletal proteins showed little difference between PC12 and PC12-C41 cells (+/- NGF treatment), there was a significant contrast between the two lines with respect to tau expression. In particular, while NGF increases the total specific levels of tau in both cell types to similar extents (by about twofold), the proportion comprising HMW tau is threefold higher in the PC12-C41 clone than in PC12 cells. A comparable difference was observed under substratum conditions that were non-permissive for neurite outgrowth and so this effect was not merely a consequence of the differential neuritogenic capacities of the two lines. The distinction between the expression of HMW and LMW taus in PC12 and PC12-C41 cells (+/- NGF) was also observed at the level of the messages encoding these proteins. Such findings indicate that initiation of neurite outgrowth in PC12 cultures does not require a massive induction of tau expression and raise the possibility that HMW and LMW taus may have differential capacities for modulating neuronal morphology.

Glycoprotein 2 of zymogen granule membranes shares immunological cross-reactivity and sequence similarity with phospholipase A2.

Glycoprotein 2 (GP2), the major protein of rat pancreatic zymogen granule membranes (ZGMs), cross-reacted with an antiserum against porcine secretory phospholipase A2 (sPLA2). Amino acid sequence comparison showed 45% similarity and 23% identity between porcine PLA2 and the C-terminal portion of GP2. An antiserum to intestinal brush border Ca(2+)-independent PLA2 (bbPLA2) also recognized GP2. The antigenic and sequence similarities between GP2, sPLA2, and bbPLA2 imply that the role of GP2 in cellular function is associated with phospholipid binding and/or hydrolysis.

Nerve growth factor and fibroblast growth factor selectively activate a protein kinase that phosphorylates high molecular weight microtubule-associated proteins. Detection, partial purification, and characterization in PC12 cells.

A cell-free assay has been developed to detect and characterize a nerve growth factor (NGF)-stimulated protein kinase activity in PC12 cells that phosphorylates high molecular weight microtubule-associated proteins (HMW-MAPs). The activity was partially purified and separated from other endogenous nonregulated HMW-MAP kinase activities by chromatography on heparin-Sepharose and Mono-Q resin. Characterization of the NGF-activated kinase (designated HMK) revealed the following features. 1) Both MAP1 and MAP2 are phosphorylated with approximately equal efficiencies. 2) Activation reaches a plateau within 3 min of NGF treatment and persists for approximately 60 min; subsequently, a substantial decline occurs by 5 h. 3) Maximal activation reaches 15-20-fold; activation is nearly as high with fibroblast growth factor, an agent that mimics NGF in promoting PC12 cell neuronal differentiation. 4) Epidermal growth factor and depolarizing levels of K+ stimulate HMK activity by only 2-4-fold; additional agents without PC12 cell differentiation activity (insulin, phorbol ester, and a permeant cAMP analogue) do not stimulate HMK activity. 5) The divalent cation requirement shows a preference for Mn2+ over Mg2+. 6) There is inhibition by 10 mM 2-aminopurine but not by 6-thioguanine, heparin, or NaF. 7) HMW-MAPs and myelin basic protein are effective substrates while histones IIIs and H1, dephospho-beta-casein, and S6 protein are not phosphorylated by HMK. These and other features appear to distinguish HMK from a variety of other well-characterized protein kinases as well as from other previously described NGF-activated kinases. The properties of HMK indicate that it could play a role in the signaling pathway for growth-factor-promoted neuronal differentiation.

Phosphorylation of the peripherin 58-kDa neuronal intermediate filament protein. Regulation by nerve growth factor and other agents.

Peripherin, a recently described member of the intermediate filament multigene family, is present in peripheral and certain central nervous system neurons as well as in cultured neuron-like cell lines, including PC12 pheochromocytoma cells. In PC12 cells, peripherin appears to be the major intermediate filament protein and its relative levels and synthesis are specifically increased during nerve growth factor (NGF)-promoted neuronal differentiation. The present study examines the phosphorylation of peripherin and the regulation thereof by nerve growth factor and other agents in cultured PC12 cells. Immunoblotting experiments using a peripherin-specific antiserum show five distinct isoforms of this protein in whole cell and cytoskeletal extracts resolved by two-dimensional isoelectric focusing sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Three of these isoforms incorporate detectable quantities of [32P]phosphate during metabolic radiolabeling. The small proportion (approximately 6%) of total cellular peripherin that is extractable with 1% Triton X-100, does not appear to incorporate phosphate. NGF increases peripherin phosphorylation by 2-3-fold within 1-2 h of treatment. Epidermal growth factor and insulin have no effect. The relative levels of phosphorylated peripherin are markedly elevated (17-fold) by long term NGF exposure, and peripherin becomes a major cytoskeletal phosphoprotein. Activators of protein kinases A and C and treatment with depolarizing levels of K+ also enhance peripherin phosphorylation by 2-3-fold, in cultures both with and without prior long term NGF treatment. Evidence is presented that NGF regulates peripherin phosphorylation by a mechanism independent of protein kinases A and C and of depolarization. The large increase in phosphorylated peripherin brought about by NGF treatment suggests that this neuronal filament protein may play a role in the elaboration and maintenance of neurites. The presence of multiple independent pathways that acutely enhance peripherin phosphorylation indicates that this role is subject to modulation by extrinsic signals.

Relationship between the nerve growth factor-regulated clone 73 gene product and the 58-kilodalton neuronal intermediate filament protein (peripherin).

Exposure of PC12 cells to nerve growth factor (NGF) has been shown to induce an mRNA that encodes a novel neuronal intermediate filament protein. The findings presented here concern the identity of this filament protein. The major protein in NGF-treated PC12 cell cytoskeletons derived by extraction with 1% Triton X-100 is of apparent Mr = 58,000, focuses by isoelectric focusing as several closely spaced spots of pl 5.6-5.8, and is elevated relative to non-NGF-treated cells. Partial microsequencing of this material reveals 2 internal sequences that are identical to a 14-residue sequence encoded by the NGF-regulated clone 73 mRNA, but not to sequences of other known proteins. An antiserum raised against a 19-residue synthetic peptide corresponding to the deduced C-terminus of the protein encoded by the NGF-regulated clone 73 mRNA specifically recognizes the 58,000-Mr protein. Properties of the 58-kilodalton protein strongly suggest that it corresponds to an intermediate filament protein (peripherin) previously identified in PC12 cells and in peripheral and certain CNS neurons. Identification of the intermediate filament protein encoded by an NGF-induced message should facilitate studies of its regulation and function.

Nerve growth factor regulates both the phosphorylation and steady-state levels of microtubule-associated protein 1.2 (MAP1.2).

This study characterizes effects of nerve growth factor (NGF) on the steady-state level and phosphorylation of a high molecular mass microtubule-associated protein in PC12 rat pheochromocytoma cells. Past work showed that NGF significantly raises the relative levels of this phosphoprotein, designated MAP1.2, with a time course similar to that of neurite outgrowth. To study this in greater detail, MAP1.2 in PC12 cell lysates was resolved by SDS-PAGE in gels containing 3.25% acrylamide/4 M urea and identified by comigration with material immunoprecipitated from the lysates by MAP1 antibodies. Quantification by metabolic radiolabeling with [35S]methionine or by silver staining revealed a 3.0-3.5-fold increase in MAP1.2 levels relative to total cell protein after NGF treatment for 2 wk or longer. A partial increase was detectable after 3 d, but not after 2 h of NGF exposure. As measured by incorporation of [32P]phosphate, NGF had a dual effect on MAP1.2. Within 15 min to 2 h, NGF enhanced the incorporation of phosphate into MAP1.2 by two- to threefold relative to total cell phosphoproteins. This value slowly increased thereafter so that by 2 wk or more of NGF exposure, the average enhancement of phosphate incorporation per MAP1.2 molecule was over fourfold. The rapid action of NGF on MAP1.2 could not be mimicked by either epidermal growth factor, a permeant cAMP derivative, phorbol ester, or elevated K+, each of which alters phosphorylation of other PC12 cell proteins. SDS-PAGE revealed multiple forms of MAP1.2 which, based on the effects of alkaline phosphatase on their electrophoretic mobilities, differ, at least in part, in extent of phosphorylation. Before NGF treatment, most PC12 cell MAP1.2 is in more rapidly migrating, relatively poorly phosphorylated forms. After long-term NGF exposure, most is in more slowly migrating, more highly phosphorylated forms. The effects of NGF on the rapid phosphorylation of MAP1.2 and on the long-term large increase in highly phosphorylated MAP1.2 forms could play major functional roles in NGF-mediated neuronal differentiation. Such roles may include effects on microtubule assembly, stability, and cross-linking and, possibly for the rapid effects, nuclear signaling.

Growth cone configuration and advance: a time-lapse study using video-enhanced differential interference contrast microscopy.

We have analyzed the dynamics of growth cone configuration using video-enhanced contrast differential interference contrast microscopy. Regenerating neurites from NGF-treated PC12 cells and sympathetic neurons were observed in real time during their elongation and reviewed by time-lapse video recordings. This technique provided a high-resolution view of motile growth cone elements including filopodia, microspikes, lamellipodia and ruffles. On the basis of our observations, a multistage model for growth cone advance is proposed. Elongation commences with lamellipodial spreading. If the newly extended lamellipodium does not retract or lift off the substrate in the form of a ruffle, a second phase--consolidation--occurs, in which the lamellipodium thickens as it fills with cytoplasm and organelles. The consolidated area then undergoes further transformation into an area of neuritic shaft as new lamellipodia form at the leading and peripheral zones of the distal process. We never observed filopodia or microspikes contracting to propel the growth cone forward. We also noted that elongating tips generally had large varicosities within 20 micron of their leading edges. These may play a role in neurite outgrowth and in the formation of smaller, synaptic vesicle-containing varicosities. The dynamic behavior of the growth cone was under the control of NGF. Withdrawal of NGF resulted in the disappearance of motile structures and cessation of growth, while readdition of NGF triggered the rapid reappearance of these structures and the resumption of growth. The high-resolution video microscopy of living growth cones provides necessary baseline information, as well as a bioassay paradigm, for future studies on the molecular mechanisms of nerve growth.