Receptor binding, internalization, and retrograde transport of neurotrophic factors.

This review deals with the receptor interactions of neurotrophic factors, focusing on the neurotrophins of the nerve growth factor (NGF) family, the glial cell derived neurotrophic factor (GDNF) family, and the ciliary neurotrophic factor (CNTF) family. The finding that two proteins, p75NTR and Trk, act as receptors for NGF in neurons generated the discovery of other neurotrophic factors/receptor families and has enhanced our understanding of the development, survival, regeneration, and degeneration of the nervous system. The kinetics of binding, the structure of the ligand-receptor complex, and the mechanism of retrograde transport of the neurotrophins are discussed in detail and compared to information available on the GDNF and CNTF families. Each neurotrophic factor family, i.e., NGF, GDNF, and CNTF, has a set of receptors with specificity for individual members of the family and a common receptor without member specificity that, in some families, generates the cellular signal and retrograde transport.

The binding of zinc and copper ions to nerve growth factor is differentially affected by pH: implications for cerebral acidosis.

It has recently been shown that transition metal cations Zn2+ and Cu2+ bind to histidine residues of nerve growth factor (NGF) and other neurotrophins (a family of proteins important for neuronal survival) leading to their inactivation. Experimental data and theoretical considerations indicate that transition metal cations may destabilize the ionic form of histidine residues within proteins, thereby decreasing their pK(a) values. Because the release of transition metal cations and acidification of the local environment represent important events associated with brain injury, the ability of Zn2+ and Cu2+ to bind to neurotrophins in acidic conditions may alter neuronal death following stroke or as a result of traumatic injury. To test the hypothesis that metal ion binding to neurotrophins is influenced by pH, the effects of Zn2+ and Cu2+ on NGF conformation, receptor binding and NGF tyrosine kinase (trkA) receptor signal transduction were examined under conditions mimicking cerebral acidosis (pH range 5.5-7.4). The inhibitory effect of Zn2+ on biological activities of NGF is lost under acidic conditions. Conversely, the binding of Cu2+ to NGF is relatively independent of pH changes within the studied range. These data demonstrate that Cu2+ has greater binding affinity to NGF than Zn2+ at reduced pH, consistent with the higher affinity of Cu2+ for histidine residues. These findings suggest that cerebral acidosis associated with stroke or traumatic brain injury could neutralize the Zn2+-mediated inactivation of NGF, whereas corresponding pH changes would have little or no influence on the inhibitory effects of Cu2+. The importance of His84 of NGF for transition metal cation binding is demonstrated, confirming the involvement of this residue in metal ion coordination.

Distinction between differentiation, cell cycle, and apoptosis signals in PC12 cells by the nerve growth factor mutant delta9/13, which is selective for the p75 neurotrophin receptor.

The common neurotrophin receptor p75(NTR) (low affinity nerve growth factor receptor) participates in the high-affinity binding with the TrkA nerve growth factor (NGF) receptor, may mediate apoptosis, and may signal independently in a cell-specific manner. The potential of p75(NTR) to signal independently of TrkA was investigated with an NGF mutant protein (NGFdelta9/13) that binds poorly to TrkA (Woo et al. [1995] J. Biol. Chem. 270:6278-6285). The NGFdelta9/13 mutant does not activate TrkA autophosphorylation and fails to stimulate the normal NGF-induced growth arrest, demonstrating that TrkA activation is required to arrest PC12 cells at the NGF-activated G1/S cell cycle checkpoint. However, apoptosis is successfully blocked and cell survival is promoted by the NGFdelta9/13 mutant in naive PC12 cells after serum withdrawal, suggesting that p75(NTR) can signal for survival autonomously of TrkA. Annexin V binding, an indication of apoptotic plasma membrane disruption, is inhibited by both NGF and the NGFdelta9/13 mutant after serum deprivation. Both NGF and the NGFdelta9/13 mutant inhibit the rapid apoptotic internucleosomal DNA cleavage of PC12 cells upon serum deprivation. Furthermore, the level of caspase3-like activity that is rapidly activated by serum withdrawal from PC12 cells is reduced by both the NGFdelta9/13 protein and NGF. Finally, upon serum withdrawal, both NGF and the NGFdelta9/13 mutant activate nuclear translocation of the transcriptional factor NF-kappaB (nuclear factor kappaB), a process involved in cell survival. These results are consistent with p75(NTR) inhibition of caspase-mediated apoptosis in PC12 cells. The different physiologic responses elicited by NGFdelta9/13 indicate the potential for individual signaling by the two NGF receptors and also demonstrate the utility of NGF mutants for receptor-selective signal transduction.

Mediation of nerve growth factor-driven cell cycle arrest in PC12 cells by p53. Simultaneous differentiation and proliferation subsequent to p53 functional inactivation.

Upon stimulation with nerve growth factor (NGF), PC12 cells extend neurites and cease to proliferate by influencing cell cycle proteins. Previous studies have shown that neuritogenesis and a block at the G(1)/S checkpoint correlate with the nuclear translocation of and an increase in the p53 tumor suppressor protein. This study was designed to determine if p53 plays a direct role in mediating NGF-driven G(1) arrest. A retroviral vector that overexpresses a temperature-sensitive p53 mutant protein (p53ts) was used to extinguish the function of endogenous p53 in PC12 cells in a dominant-negative manner at the nonpermissive temperature. NGF treatment led to transactivation of a p53 response element in a luciferase reporter construct in PC12 cells, whereas this response to NGF was absent in PC12(p53ts) cells at the nonpermissive temperature. With p53 functionally inactivated, NGF failed to activate growth arrest, as measured by bromodeoxyuridine incorporation, and also failed to induce p21/WAF1 expression, as measured by Western blotting. Since neurite outgrowth proceeded unharmed, 50% of the cells simultaneously demonstrated neurite morphology and were in S phase. Both PC12 cells expressing SV40 T antigen and PC12 cells treated with p53 antisense oligonucleotides continued through the cell cycle, confirming the dependence of the NGF growth arrest signal on a p53 pathway. Activation of Ras in a dexamethasone-inducible PC12 cell line (GSRas1) also caused p53 nuclear translocation and growth arrest. Therefore, wild-type p53 is indispensable in mediating the NGF antiproliferative signal through the Ras/MAPK pathway that regulates the cell cycle of PC12 cells.

A TrkA-selective, fast internalizing nerve growth factor-antibody complex induces trophic but not neuritogenic signals.

Nerve growth factor (NGF) is a neurotrophin that induces neuritogenic and trophic signals by binding to TrkA and/or p75 receptors. We report a comparative study of the binding, internalization, and biological activity of NGF versus that of NGF in association with an anti-NGF monoclonal antibody (mAb NGF30), directed against the C termini of NGF. NGF.mAb complexes do not bind p75 effectively but bind TrkA with high affinity. After binding, NGF. mAb complexes stimulate internalization faster and to a larger degree than NGF. NGF.mAb-induced activation of TrkA, Shc, and MAPK is transient compared with NGF-induced activation; yet NGF and NGF. mAb afford identical trophic responses. In contrast, NGF induces Suc-1-associated neurotrophic activating protein phosphorylation and neuritogenic differentiation, but NGF.mAb does not. Thus, an absolute separation of trophic and neuritogenic function is seen for NGF.mAb, suggesting that biological response modifiers of neurotrophins can afford ligands with selected activities.

Characterization of the recombinant extracellular domain of the neurotrophin receptor TrkA and its interaction with nerve growth factor (NGF).

Nerve growth factor (NGF) is the prototype of a family of neurotrophins that support important neuronal programs such as differentiation and survival of a subset of sympathetic, sensory, and brain neurons. NGF binds to two classes of cell surface receptors: p75LANR and p140TrkA. NGF binding to p140TrkA initiates the neuronal signaling pathway through activation of the tyrosine kinase activity, which subsequently results in a rapid signal transduction through a phosphorylation cascade. To examine this crucial signaling step in more detail, the TrkA extracellular domain polypeptide (TrkA-RED) was overexpressed in Sf21 insect cells and purified to homogeneity. The recombinant TrkA-RED is a 70 kDa acidic glycoprotein with a pI of 5.1, and mimics the intact TrkA receptor for NGF binding with a dissociation constant, Kd, of 2.9 nM. Thus, the recombinant TrkA-RED is functionally competent and can be used to elucidate the interaction of NGF and TrkA receptor. Circular dichroism difference spectra indicated that, upon association of NGF with TrkA-RED, a minor conformational change occurred to form a complex with decreased ordered secondary structure. Interaction between NGF and TrkA-RED was also demonstrated by size exclusion chromatography, light scattering, and chemical crosslinking with evidence for formation of a higher molecular weight complex consistent with a (TrkA-RED)2-(NGF dimer) complex. Association and dissociation rates of 5.6 x 10(5) M(-1) s(-1) and 1.6 x 10(-3) s(-1), respectively, were determined by biosensor technology. Thus, initiation of signaling may stem from NGF-induced receptor dimerization concomitant with a small conformational change.

Different mechanisms for inhibition of cell proliferation via cell cycle proteins in PC12 cells by nerve growth factor and staurosporine.

PC12 cells have previously been shown to cease cell division during nerve growth-factor (NGF)-induced differentiation by affecting specific cell cycle proteins. Staurosporine, a protein kinase inhibitor, also causes PC12 cell differentiation, independently of neurotrophins or plasma membrane receptors. We have investigated the relationship of the tumor suppressor protein, p53, and other cell cycle proteins to the antiproliferative effects of NGF and staurosporine in PC12 cells. NGF treatment of PC12 cells stimulated an increase of p53 protein in the nucleus and, more slowly, an increase in total cellular p53 protein. Levels of the cyclin-kinase inhibitor p21/WAF1, cyclin D1, and cyclin G, all downstream transcriptional targets of p53, increased after short times of NGF treatment. Cessation of replication and differentiation occurred more rapidly in defined medium (2 days) than in serum medium (6 days), in correspondence with the more rapid changes in both p53 and p21/WAF1 levels in defined medium (1 hour) than in serum (1 day). Levels of p34cdc2 and p33cdk2 kinase dropped after 6 to 10 days treatment with NGF in serum, close to the time of terminal differentiation. Staurosporine, on the other hand, inhibited DNA replication of PC12 cells in a time- and dose-dependent fashion by affecting cyclin-dependent kinases. Staurosporine had no effect on the protein levels of p53, p21/WAF1, or cyclin G. The kinase activity of both p34cdc2 and p33cdk2 were inhibited in vitro with IC50 values of 20 nM and 75 nM, respectively. In vivo p34cdc2 kinase activity was inhibited within 1 day, before the decrease in the levels of p34cdc2 protein at days 2 to 3. In contrast, in vivo p33cdk2 kinase activity only decreased in concert with protein levels. Although both NGF and staurosporine inhibit DNA replication concomitant with induction of differentiation by affecting the activity of p34cdc2 and p33cdk2, the mechanism of the two agents is quite different. NGF achieves inhibition of activity of these cyclin-dependent kinases by signalling through the TrkA receptor to the tumor suppressor protein p53 and then to p21/WAF1. In contrast, staurosporine directly inhibits the activity of p34cdc2 and p33cdk2 by binding to them and also indirectly by alteration of their phosphorylation through other regulatory kinases.

Characterization of histidine residues essential for receptor binding and activity of nerve growth factor.

The role of the four histidine residues in receptor binding and activity of mouse nerve growth factor (NGF) was investigated using both site-directed mutagenesis and chemical modification with diethyl pyrocarbonate. Replacement of His-75 or His-84 with alanine resulted in decreased biological activity and decreased affinity for p140(trkA); however, with H75A only, a 5-fold increased affinity toward p75(LANR) was observed. The effect of simultaneous replacement of both His-75 and His-84 was neither additive nor synergistic. Slight perturbations in circular dichroism spectra and weakened self-association of the mutants indicated that His-75 and His-84 may be involved in stability, dimerization, and/or folding of NGF. Diethyl pyrocarbonate modification of His-4 and His-8 in the H75A/H84Q double mutant abolished neuritogenesis, binding to both receptors, and phosphorylation of p140(trkA) in PC12 cells. These chemical and mutational results confirm and clarify previous evidence for the involvement of His-75 and His-84 (Dunbar, J. C., Tregear, G. W., and Bradshaw, R. A. (1984) J. Protein Chem. 3, 349-356) or His-4 and His-8 (Shih, A., Laramee, G. R., Schmelzer, C. H., Burton, L. E., and Winslow, J. W. (1994) J. Biol. Chem. 269, 27679-27686) in receptor binding of NGF. At least three and possibly all four histidines, which are located in three spatially distinct regions, contribute to maintenance of functional sites that are essential for receptor binding and activity of NGF.

Mutational studies of conserved residues in the dimer interface of nerve growth factor.

An understanding of the structure-function relationship of nerve growth factor (NGF) requires precise knowledge of all the residues and regions that participate in NGF receptor binding, receptor activation, and biological activity. Seven recombinant human NGF mutants having alanine substituted for residues located either in the NGF dimer interface or beta-strand region were studied to determine the role of each amino acid residue in NGF biological activity. F86A, T91A, R100A, and R103A remained nearly full active with 61, 120, 91, and 73% of wild-type activity, respectively, in the PC12 cell bioassay. Hydrophobic core and dimer interface residues Y52, F53, and F54 were studied in more detail. Y52A and F54A were expressed in very low levels, suggesting that these two residues may be important for protein stability. Y52A retained full biological activity (91%). F53A had a 20- and 70-fold reduction in biological activity and TrkA phosphorylation, respectively, with only a 5- to 10-fold effect on TrkA binding and no effect on low-affinity receptor binding. F54A had significantly decreased TrkA phosphorylation and biological activity (40-fold). The results suggest that F53 and F54 may play a structural role in TrkA receptor activation subsequent to binding.

Hierarchical analysis of the nerve growth factor-dependent and nerve growth factor-independent differentiation signaling pathways in PC12 cells with protein kinase inhibitors.

The effects of a series of protein kinase inhibitors on nerve growth factor (NGF)-dependent and NGF-independent neurite outgrowth in PC12 cells have established an ordered relationship among those protein kinases sensitive to down regulation by bryostatin, stimulation by staurosporine, inhibition by sphingosine, or inhibition by 6-thioguanine (6-TG). Quantitation of the biphasic staurosporine effects on NGF-induced neurite outgrowth (Hashimoto and Hagino: J Neurochem 53:1675-1685, 1989) gave an IC50 of 2-4 nM for inhibition and an EC50 of 15-20 nM for induction of neurite extension. Both sphingosine and 6-TG inhibited neurite outgrowth induced by staurosporine and basic fibroblast derived growth factor (bFGF), as well as by NGF; therefore, sphingosine- and 6-TG-sensitive protein kinase steps occur after the convergence of the NGF, bFGF, and staurosporine signal pathways. Down regulation of protein kinase C by bryostatin chronic treatment, which inhibits NGF- and bFGF-induced neuritogenesis (Singh et al.: Biochemistry 33:542-551, 1994), did not inhibit the staurosporine-induced neurite outgrowth. Thus, the bryostatin-sensitive protein kinase C must occur subsequent to the convergence of the bFGF and NGF pathways, but before (or parallel to) staurosporine initiation of neurite outgrowth. In contrast, low concentrations of phorbol myristoyl acetate (PMA) or bryostatin, which activate protein kinase C activity, enhanced the staurosporine- or NGF-induced neurite extension. These data indicate that stimulation of one or more protein kinase C isozymes can synergistically interact with the signaling pathway to increase the rate of neuritogenesis. Inhibition by 5-7.5 nM staurosporine acted rapidly to arrest and decrease development of neurites up to 24 hr after NGF treatment, as did K252a and NGF polyclonal antibody addition. Our cellular data support the concept that staurosporine acts to inhibit the NGF receptor Trk (Nye et al.: Mol Biol Cell 3:677-686, 1992), but that downstream steps can be activated by the higher concentration of staurosporine to bypass Trk and lead to neurite generation. Effects of staurosporine, 6-TG, and sphingosine on c-fos gene induction with or without NGF were not correlated with the generation of neurites. The sequence of protein kinases sensitive to these effectors appears to be in the order (but not consecutive) bryostatin, staurosporine, sphingosine, and 6-TG.

Alteration of NH2-terminal residues of nerve growth factor affects activity and Trk binding without affecting stability or conformation.

The role of the NH2-terminal region of nerve growth factor (NGF) was studied with an NGF delta 9/13 deletion mutant, overexpressed in a baculovirus system, and mouse NGF truncated at Met-9 by cleavage with CNBr (des-(1-9)-NGF). Structural studies have been performed on the purified proteins, in addition to biological activity assessment, in order to determine effects of such modifications on global conformation and stability. The activity of NGF delta 9/13 was reduced below detectable levels, and the activity of the des-(1-9)-NGF form was decreased by at least a 50-fold in a PC12 bioassay. Competitive binding of NGF delta 9/13 to low affinity receptors on PC12 cells was not impaired; however, the mutant was not capable of competing for the cold chase-stable, high affinity binding of NGF to the cells. The binding of NGF delta 9/13 to Sf21 cells ectopically expressing the TrkA NGF receptor was also abolished. Thus, deletion of residues 9-13 significantly altered the binding affinity for the high affinity receptors on PC12 cells and for the TrkA receptor, but not for the low affinity receptor. Neither the secondary structure, determined by circular dichroism, nor the conformational stability determined by equilibrium denaturation of NGF delta 9/13 was altered as compared with wild type NGF. Slight conformational and stability perturbations of des-(1-9)-NGF were revealed by the same analysis; however, these changes were found to reflect the influence of the formic acid treatment, not the truncation of 9 residues. Our results support the conclusion that the NH2-terminal domain encompassing residues 1-9 and 9-13 is essential for maintaining the binding capability of NGF for high affinity TrkA receptors. Moreover, conformational and stability data show that the functional results of these modifications of the NH2-terminal region are directly due to receptor binding and not to secondary effects of improper folding or other indirect structural changes.

Conformational stability of dimeric proteins: quantitative studies by equilibrium denaturation.

The conformational stability of dimeric globular proteins can be measured by equilibrium denaturation studies in solvents such as guanidine hydrochloride or urea. Many dimeric proteins denature with a 2-state equilibrium transition, whereas others have stable intermediates in the process. For those proteins showing a single transition of native dimer to denatured monomer, the conformational stabilities, delta Gu (H2O), range from 10 to 27 kcal/mol, which is significantly greater than the conformational stability found for monomeric proteins. The relative contribution of quaternary interactions to the overall stability of the dimer can be estimated by comparing delta Gu (H2O) from equilibrium denaturation studies to the free energy associated with simple dissociation in the absence of denaturant. In many cases the large stabilization energy of dimers is primarily due to the intersubunit interactions and thus gives a rationale for the formation of oligomers. The magnitude of the conformational stability is related to the size of the polypeptide in the subunit and depends upon the type of structure in the subunit interface. The practical use, interpretation, and utility of estimation of conformational stability of dimers by equilibrium denaturation methods are discussed.

Comparative equilibrium denaturation studies of the neurotrophins: nerve growth factor, brain-derived neurotrophic factor, neurotrophin 3, and neurotrophin 4/5.

The neurotrophins are a family of small dimeric proteins required for the development and survival of vertebrate neurons. Solvent denaturation studies were used to compare recombinant human nerve growth factor (hNGF), brain-derived neurotrophic factor (BDNF), neurotrophin 3 (NT-3), and neurotrophin 4/5 (NT-4/5) to nerve growth factor isolated from mouse submaxillary glands (mNGF). Although greater than 50% sequence identity is conserved among this family, significant structural differences were revealed by the folding and unfolding of these proteins. Denaturation in guanidine hydrochloride and renaturation at pH 7 and 3.5 were monitored by fluorescence intensity, fluorescence polarization, and circular dichroism. The midpoint of equilibrium unfolding curves for all four neurotrophins was independent of the technique but was dependent on protein concentration, indicating that a two-state model involving native neurotrophin dimers and denatured neurotrophin monomers (N2 = 2D) describes the equilibrium between folded and unfolded neurotrophins. The conformational stabilities of the dimeric neurotrophins revealed that mNGF had the lowest conformational stability (19.3 kcal/mol); hNGF, NT-3, and NT-4/5 had intermediate stabilities, and BDNF had the highest stability (26.4 kcal/mol). Recovery of native spectroscopic characteristics upon removal of denaturant indicated that the unfolding process is reversible. Accordingly, unfolding and refolding curves were coincident for mNGF or NT-4/5 at pH 7 and 3.5 and for BDNF at pH 3.5. However, BDNF and NT-3 unfolding and refolding curves were not coincident at pH 7. The stability of the neurotrophins decreased as pH decreased, with compact monomeric intermediates (N2 = [2I] = 2D) becoming populated below pH 4. The differences in stability, pH dependence, and coincidence of refolding curves distinguish the homologous structures of the neurotrophins.

Circular dichroism and crosslinking studies of the interaction between four neurotrophins and the extracellular domain of the low-affinity neurotrophin receptor.

Interactions between the purified recombinant receptor extracellular domain (RED) of the human low-affinity neurotrophin receptor (LANR) and recombinant human brain-derived neurotrophic factor, neurotrophin-3 (NT-3) and neuotrophin-4/5 have been studied by chemical crosslinking and circular dichroism. Conformational changes subsequent to binding have been shown by these procedures. First, relative affinities of the neurotrophins for RED were determined by binding competition assays in which radioiodinated nerve growth factor (NGF) from mouse submaxillary gland was crosslinked to RED in the presence of varying amounts of unlabeled neurotrophin competitors. RED bound each of the 3 recombinant human neurotrophins with affinities that were indistinguishable from authentic mouse NGF. These results are the first measurement of binding of the neurotrophin family to their common receptor using purified components. In order to study the effect of binding on the conformation of the proteins, CD measurements were made before and after mixing neurotrophins and RED, as had previously been done with NGF and RED (Timm DE, Vissavajjhala P, Ross AH, Neet KE, 1992, Protein Sci 1:1023-1031). Similar changes in CD spectra occurred upon combination of each of the neurotrophins and RED, with negative changes near 220-225 nm and positive changes near 190-200 nm; however, significant differences existed among the various neurotrophin-RED difference spectra. The NT-3/RED complex showed the largest spectral change and NGF the smallest. Thus, specific conformational changes in secondary structure of neurotrophin, RED, or both accompany the binding of each neurotrophin to the extracellular domain of the LANR.

Immunological determinants of nerve growth factor involved in p140trk (Trk) receptor binding.

Monoclonal anti-NGF antibodies that specifically inhibit the biological activity of mouse beta-NGF were used to study the structural determinants involved in the interaction of NGF with its receptors gp75LNGFR and Trk. None of the three antibodies--N60, M15, and 27/21--showed any reactivity toward denatured NGF. Three experimental methods--radioimmunoassay (RIA), enzyme-linked immunoassay (ELISA), and slot blots--detected no significant cross reactivity between the antibodies and BDNF or NT-3. RIA showed that M15 and N60 recognize the same or an overlapping antigenic site, but 27/21 recognizes a different epitope. Only 27/21, and not N60 or M15, immunoprecipitated beta-NGF crosslinked to LNGFR receptor. Thus, the epitope recognized by 27/21 does not overlap the LNGFR receptor binding site. N60, M15, and 27/21 all block binding of NGF to Trk in a manner consistent with competitive inhibition. Purified Fab fragments of N60 and M15 gave similar results to the intact antibodies. The other subunits present in the 7S complex of NGF, i.e. the alpha and gamma subunits, competitively inhibited binding of antibodies to beta-NGF. Only the gamma subunit inhibited phosphorylation of Trk and biological activity of beta-NGF. These findings suggest that the M15, N60, and 27/21 antibodies bind to a specific site on the surface of NGF where they competitively inhibit binding to the Trk NGF receptor. The region encompassing the N-terminus, the C-terminus, and the loop on the surface of beta-NGF containing residues 60-80 is proposed as important for binding to the Trk receptor.

A bryostatin-sensitive protein kinase C required for nerve growth factor activity.

Nerve growth factor (NGF) stimulates rat pheochromocytoma cells (PC12) to differentiate into a neuronal-like cell that exhibits neurite extensions. The role of protein kinase C in signal transduction has been examined in PC12 cells treated with phorbol 12-myristate 13-acetate (PMA) and bryostatin, a macrocyclic lactone that activates protein kinase C at both the nuclear and the plasma membranes [Hocevar, B. A., & Fields, A. P. (1991) J. Biol. Chem. 266, 28-33]. In contrast to PMA down-regulation [Reinhold, D. S., & Neet, K. E. (1989) J. Biol. Chem. 264, 3538-3544], chronic (24 h) treatment with bryostatin blocked the formation of neurites in response to NGF or basic fibroblast-derived growth factor stimulation, but, like PMA, bryostatin did not block the induction of c-fos or c-jun protooncogenes by NGF. Chronic bryostatin treatment down-regulated protein kinase C activity in the cytosolic, membrane, and nuclear fractions. Acute (60 min) bryostatin or NGF treatment activated cytosolic and nuclear protein kinase C activity, suggesting possible translocation to the nucleus. Bryostatin did not induce neurite outgrowth, either alone or in combination with PMA. Thus, the bryostatin-sensitive protein kinase C is distinct from PMA- or K252a-sensitive kinases previously described. The bryostatin-sensitive protein kinase C is necessary, but not sufficient, for neurite outgrowth and acts in the nucleus in a manner independent of c-fos and c-jun transcription.

Flow cytometric analysis of fluorescein-labeled nerve growth factor binding to A875 human melanoma cells.

The interaction of fluorescein-labeled nerve growth factor (NGF) with human melanoma cells (A875) has been studied in order to assess better methodology for rigorous NGF binding studies. The NGF was modified at a single carboxyl group with iodoacetamidofluorescein after reaction with carbodiimide and cystamine. The modified NGF showed full binding competence in competition with radiolabeled NGF and full biological activity in neurite outgrowth assays compared to native NGF. Binding to unfixed, viable cells was assayed using flow cytometry. This method offers the advantage that unbound ligand need not be separated from that which is cell-associated, thus avoiding perturbation of the binding equilibrium, and accurate, extensive statistical analysis is possible. Binding of fluorescein-NGF was mainly specific and saturable, with analysis by three methods of data treatment indicating a Kd of 0.8 to 3 nM at 4 degrees C. Time-based data acquisition allowed a continuous time course for binding to be generated. Binding reached a steady-state level within 5 min of exposure of the cells to the ligand. Kinetic and steady-state results obtained using fluorescein-NGF agree well with previous data produced by 125I-NGF binding studies. The main limitation of the flow cytometric method in the NGF system is the relative lack of sensitivity compared to the binding of radiolabeled NGF, partially due to unusual quenching of the fluorophore bound to NGF.

Characterization of the lectin from the bulbs of Eranthis hyemalis (winter aconite) as an inhibitor of protein synthesis.

The lectin from Eranthis hyemalis has been previously characterized as consisting of two polypeptide chains covalently linked by disulfide bond(s) (Cammue, B. P., Peeters, B., and Peumans, W. J. (1985) Biochem. J. 227, 949-955). We have further characterized the biochemical properties of the lectin and demonstrated that it possesses the property of inhibition of protein synthesis using in vitro eukaryotic translation systems. The protein also possesses antiviral activity against the plant virus, alfalfa mosaic virus, and larvicidal activity against the southern corn rootworm, Diabrotica undecimpunctata howardii, a major insect pest of the maize plant. Both isoelectric focusing on gels and chromatofocusing indicated heterogeneity of the protein, with three species having isoelectric points in the range 4-5. The disulfide bond(s) can be rapidly reduced with beta-mercaptoethanol under native conditions. The reduced alkylated polypeptide chains remain associated under native conditions to form a species, EHL', that elutes at the same position as the native protein and has the same molecular weight by sedimentation equilibrium experiments. However, circular dichroism and fluorescence measurements indicated conformational differences between the species.