p75 Co-receptors regulate ligand-dependent and ligand-independent Trk receptor activation, in part by altering Trk docking subdomains.

Neurotrophins signal via Trk tyrosine kinase receptors and a common receptor called p75. Nerve growth factor is the cognate ligand for TrkA, brain-derived neurotrophic factor for TrkB, and neurotrophin-3 (NT-3) for TrkC. NT-3 also binds TrkA and TrkB as a heterologous ligand. All neurotrophins bind p75, which regulates ligand affinity and Trk signals. Trk extracellular domain has five subdomains: a leucine-rich motif, two cysteine-rich clusters, and immunoglobulin-like subdomains IgG-C1 and IgG-C2. The IgG-C1 subdomain is surface exposed in the tertiary structure and regulates ligand-independent activation. The IgG-C2 subdomain is less exposed but regulates cognate ligand binding and Trk activation. NT-3 as a heterologous ligand of TrkA and TrkB optimally requires the IgG-C2 but also binds other subdomains of these receptors. When p75 is co-expressed, major changes are observed; NGF-TrkA activation can occur also via the cysteine 1 subdomain, and brain-derived neurotrophic factor-TrkB activation requires the TrkB leucine-rich motif and cysteine 2 subdomains. We propose a two-site model of Trk binding and activation, regulated conformationally by the IgG-C1 subdomain. Moreover, p75 affects Trk subdomain utilization in ligand-dependent activation, possibly by conformational or allosteric control.

Developmental expression patterns of the signaling adapters FRS-2 and FRS-3 during early embryogenesis.

Two fibroblast growth factor (FGF) receptor substrates (FRS2 and FRS3) are involved in downstream signaling from activated FGF receptors and neurotrophin-activated Trk receptors. Despite the importance of signaling from these factors in embryogenesis, FRS2 and FRS3 expression patterns during development are unknown. In this study we characterize the expression of FRS2 and FRS3 from E7 to parturition and in adult murine tissues. Both are first detected in whole E8.5 CD1 mouse embryos. FRS2 is detected as early as E7 in the developing syncytiotrophoblast, later in the neural tube (NT) and in many adult and fetal tissues. FRS3 is more restricted in location than FRS2 (fetal NT, heart, stomach, liver and some adult tissues), and is expressed predominantly in the ventricular layer of the developing NT and brains of murine embryos.

A differential role of extracellular signal-regulated kinase in stimulated PC12 pheochromocytoma cell movement.

Rat pheochromocytoma PC12 cells have been widely used as a cell system for study of growth factor-stimulated cell functions. We report here that nerve growth factor (NGF) stimulated both chemotaxis (directional migration) and chemokinesis (random migration) of PC12 cells. Treatment with a MEK1/2-specific inhibitor (PD98059) or expression of a dominant negative variant of Ras differentially inhibited NGF-stimulated chemotaxis but not chemokinesis of PC12 cells. Priming of PC12 cells with NGF resulted in reduced extracellular signal-regulated kinase (ERK) activation and loss of chemotactic, but not chemokinetic, response. In addition, NGF stimulation of ERK is known to involve an early transient phase of activation followed by a late sustained phase of activation; in contrast, epidermal growth factor (EGF) elicits only early transient ERK activation. We observed that like NGF, EGF also stimulated both chemotaxis and chemokinesis, and treatment with PD98059 abolished the EGF-stimulated chemotaxis. Therefore, the early transient phase of ERK activation functioned in signaling chemotaxis; the late sustained phase of ERK activation did not seem to have an essential role. In addition, our results suggested that chemotactic signaling required a threshold level of ERK activation; at below threshold level of ERK activation, chemotaxis would not occur.

Direct binding of the signaling adapter protein Grb2 to the activation loop tyrosines on the nerve growth factor receptor tyrosine kinase, TrkA.

We demonstrate that the signaling adapter, Grb2, binds directly to the neurotrophin receptor tyrosine kinase, TrkA. Grb2 binding to TrkA is independent of Shc, FRS-2, phospholipase Cgamma-1, rAPS, and SH2B and is observed in in vitro binding assays, yeast two-hybrid assays, and in co-immunoprecipitation assays. Grb2 binding to TrkA is mediated by the central SH2 domain, requires a kinase-active TrkA, and is phosphotyrosine-dependent. By analyzing a series of rat TrkA mutants, we demonstrate that Grb2 binds to the carboxyl-terminal residue, Tyr(794), as well as to the activation loop tyrosines, Tyr(683) and Tyr(684). By using acidic amino acid substitutions of the activation loop tyrosines on TrkA, we can stimulate constitutive kinase activity and TrkA-Shc interactions but, importantly, abolish TrkA/Grb2 binding. Thus, in addition to providing the first evidence of direct Grb2 binding to the neurotrophin receptor, TrkA, these data provide the first direct evidence that the activation loop tyrosines of a receptor tyrosine kinase, in addition to their essential role in kinase activation, also serve a direct role in the recruitment of intracellular signaling molecules.

Acidic substitution of the activation loop tyrosines in TrkA supports nerve growth factor-independent cell survival and neuronal differentiation.

TrkA is the receptor tyrosine kinase (RTK) for nerve growth factor (NGF) and stimulates NGF-dependent cell survival and differentiation in primary neurons. TrkA expression in neuronal tumors also supports NGF-dependent differentiation of neuroblastomas and apoptosis of medulloblastomas. Phosphorylation of the activation loop tyrosines in RTK's are essential to activation as well as allosteric changes that facilitate substrate interaction and phosphorylation. Acidic amino acid substitution of the activation loop tyrosines in TrkA, Tyr683Tyr684, was performed to mimic the negative charges normally induced by ligand activation and receptor phosphorylation. A total of eight independent mutants containing single or double substitutions were generated for comparison. Herein, we demonstrate that acidic substitution of the activation loop tyrosines is sufficient to induce allosteric changes required for constitutive TrkA kinase activity as well as phosphorylation of TrkA signaling proteins such as Shc, PLCgamma-1, FRS-2 and erk1/2. The strongest constitutively active TrkA mutants, GluAsp and AspGlu, support NGF-independent neuritogenesis and cell survival to levels approximately 65 and 80-100%, respectively, of NGF-activated wild type TrkA. Thus, constitutively active TrkA may provide a useful strategy in future therapeutic approaches to limit the development and progression of neuronal tumors.

Subpopulations of rat B2(+) neuroblasts exhibit differential neurotrophin responsiveness during sympathetic development.

Sympathetic neurons comprise a population of postmitotic, tyrosine hydroxylase expressing cells whose survival is dependent upon nerve growth factor (NGF) both in vivo and in vitro. However, during development precursors to rat sympathetic neurons in the thoracolumbar region are not responsive to NGF because they lack the signal transducing NGF receptor, trkA. We have previously shown that acquisition of trkA expression is sufficient to confer a functional response to NGF. Here we describe four subpopulations of thoracolumbar sympathetic neuroblasts which are mitotically active and unresponsive to NGF at E13.5 of rat gestation, but differ based upon their neurotrophic responsiveness in vitro. The survival in culture of the largest sympathetic subpopulation is mediated by neurotrophin-3 (NT-3) or glial-derived neurotrophic factor (GDNF), whereas the cell survival of two smaller subpopulations of neuroblasts are mediated by either solely GDNF or solely NT-3. Finally, we identify a subpopulation of sympathetic neuroblasts in the thoracolumbar region whose survival, exit from the cell cycle, induction of trkA expression, and consequent acquisition of NGF responsiveness in culture appear to be neurotrophin independent and cell autonomous. These subpopulations reflect the diversity of neurotrophic actions that occur in the proper development of sympathetic neurons.

Distinct human NUMB isoforms regulate differentiation vs. proliferation in the neuronal lineage.

Neuronal cell fate decisions are directed in Drosophila by NUMB, a signaling adapter protein with two protein-protein interaction domains: a phosphotyrosine-binding domain and a proline-rich region (PRR) that functions as an SH3-binding domain. Here we show that there are at least four human NUMB isoforms and that these serve two distinct developmental functions in the neuronal lineage: differentiation (but not proliferation) is promoted by human NUMB protein isoforms with a type I (short) PRR. In contrast, proliferation (but not differentiation) is directed by isoforms that have a type II (long) PRR. The two types of PRR may promote distinct intracellular signaling pathways downstream of the NOTCH receptor during mammalian neurogenesis.

Neutralizing intraspinal nerve growth factor blocks autonomic dysreflexia caused by spinal cord injury.

Autonomic dysreflexia is a condition that develops after spinal cord injury in which potentially life-threatening episodic hypertension is triggered by stimulation of sensory nerves in the body below the site of injury. Central sprouting of small-diameter primary afferent fibers in the dorsal horn of the spinal cord occurs concurrently with the development of this condition. We propose a model for the development of autonomic dysreflexia in which increased nerve growth factor (NGF) in the injured cord stimulates small-diameter primary afferent fiber sprouting, thereby magnifying spinal sympathetic reflexes and promoting dysreflexia. We identified this population of afferent neurons using immunocytochemistry for calcitonin gene-related peptide. Blocking intraspinal NGF with an intrathecally-delivered neutralizing antibody to NGF prevented small-diameter afferent sprouting in rats 2 weeks after a high thoracic spinal cord transection. In the same rats, this anti-NGF antibody treatment significantly decreased (by 43%) the hypertension induced by colon stimulation. The extent of small-diameter afferent sprouting after cord transection correlated significantly with the magnitude of increases in arterial pressure during the autonomic dysreflexia. Neutralizing NGF in the spinal cord is a promising strategy to minimize the life-threatening autonomic dysreflexia that develops after spinal cord injury.

The signaling adapter FRS-2 competes with Shc for binding to the nerve growth factor receptor TrkA. A model for discriminating proliferation and differentiation.

We have isolated a human cDNA for the signaling adapter molecule FRS-2/suc1-associated neurotrophic factor target and shown that it is tyrosine-phosphorylated in response to nerve growth factor (NGF) stimulation. Importantly, we demonstrate that the phosphotyrosine binding domain of FRS-2 directly binds the Trk receptors at the same phosphotyrosine residue that binds the signaling adapter Shc, suggesting a model in which competitive binding between FRS-2 and Shc regulates differentiation versus proliferation. Consistent with this model, FRS-2 binds Grb-2, Crk, the SH2 domain containing tyrosine phosphatase SH-PTP-2, the cyclin-dependent kinase substrate p13(suc1), and the Src homology 3 (SH3) domain of Src, providing a functional link between TrkA, cell cycle, and multiple NGF signaling effectors. Importantly, overexpression of FRS-2 in cells expressing an NGF nonresponsive TrkA receptor mutant reconstitutes the ability of NGF to stop cell cycle progression and to stimulate neuronal differentiation.

Activity-dependent interaction of the intracellular domain of rat trkA with intermediate filament proteins, the beta-6 proteasomal subunit, Ras-GRF1, and the p162 subunit of eIF3.

Many responses to nerve growth factor (NGF) are regulated through the receptor tyrosine kinase trkA. To understand more fully the functions of trkA in NGF responsive cells, we have expressed the intracellular domain of rat trkA as a fusion protein with the yeast gal4 transcription factor, and used the fusion protein to probe rat and mouse cDNA libraries by the yeast two-hybrid system. We have identified a direct interaction between the intracellular domain of trkA and two members of the intermediate filament (IF) family of proteins, the guanine-nucleotide exchange protein Ras-GRF1, the p162 subunit of eIF3, and the beta-6 proteasome subunit. The interactions are dependent on an active trkA kinase, and RasGRF1, the beta-6 proteasomal subunit, and peripherin are directly phosphorylated by trkA. The interaction with trkA is not affected by mutations at either Tyr499 or Tyr794, the two major phosphotyrosine residues essential to the activation and receptor binding of Shc, FRS-2/SNT, and phospholipase Cgamma-1, and it is highly specific in vitro for trkA, with little or no binding observed with trkB and/or trkC. The results show that trkA may play a regulatory role in a variety of cellular functions in addition to neuritogenesis, including regulated protein degradation and transcriptional activation.

A novel juxtamembrane deletion in rat TrkA blocks differentiative but not mitogenic cell signaling in response to nerve growth factor.

We have generated a novel rat TrkA receptor mutant (TrkAS3) by deletion of five conserved residues (493IMENP497) in the juxtamembrane domain. TrkAS3 receptors cannot support nerve growth factor (NGF)-induced cell cycle arrest or neuronal differentiation but retain cell survival responses as well as Ras-dependent mitogenic signaling. Cells of the nnr5 line stably expressing TrkAS3 induce NGF-dependent SHC phosphorylation and phosphatidylinositol 3-kinase, phospholipase Cgamma-1, and prolonged mitogen-activated protein kinase activation to absolute levels comparable to those in PC12 cells. Although the stoichiometry of TrkAS3-SHC binding is reduced, cells overexpressing TrkAS3 exhibit NGF-dependent SHC-Grb-2/Sos binding, essential for Ras activation, as well as NGF-dependent SNT phosphorylation to absolute levels comparable to those in PC12 cells. Collectively, these data suggest that the TrkAS3 deletion either directly affects a novel Ras-independent TrkA binding protein or that the decrease in TrkAS3-SHC association affects a Ras-independent SHC binding protein essential for cell cycle arrest and/or neurite outgrowth.

A kinase insert isoform of rat TrkA supports nerve growth factor-dependent cell survival but not neurite outgrowth.

To investigate potential differences between the family of Trk receptors that might have differential consequences on cell signaling, we generated a rat TrkA homologue of the 14-amino acid kinase insert isoform of TrkC termed TrkAKi. Signal transduction by the TrkAKi receptor has been investigated and compared with the homologous signaling defective TrkC(Ki14) receptor. Herein, we demonstrate that TrkAKi receptors show a decrease in the absolute amount of kinase activity relative to wild-type TrkA, yet retain normal patterns of receptor tyrosine phosphorylation, as determined by phosphopeptide mapping studies, unlike TrkC(Ki14). nnr5 cell clones expressing TrkAKi receptors show a decrease in nerve growth factor (NGF)-mediated SHC tyrosine phosphorylation and a loss of high-affinity TrkA-SHC interaction comparable to those expressing TrkC(Ki14). Moreover, nnr5 cells expressing TrkAKi receptors fail to demonstrate NGF-dependent tyrosine phosphorylation of the signaling molecules phospholipase Cgamma-1, MAP kinase/ERK-1, and SNT. TrkAKi receptors internalize NGF comparable to wild-type TrkA, but do not stimulate neurite outgrowth. It is interesting that, unlike TrkC(Ki14), TrkAKi receptors retain phosphatidylinositol 3-kinase activity and nnr5 cells stably expressing TrkAKi receptors retain NGF-dependent cell survival under serum-free conditions. Lastly, TrkAKi receptors fail to stimulate three immediate-early genes (NGF1A, NGF1B, and c-fos), suggesting that these gene products are not required for NGF-dependent cell survival responses.

Deletions in the extracellular domain of rat trkA lead to an altered differentiative phenotype in neurotrophin responsive cells.

We have investigated the role(s) of conserved sequences in the extracellular domain of rat trkA by generating 5' and 3' deletions and assaying changes in neurotrophin binding, tyrosine kinase activity, and neurite outgrowth. Essential sequences required for both nerve growth factor (NGF) and neurotrophin-3 (NT-3) binding were mapped to the immunoglobulin-like domains. Small deletions in the second immunoglobulin-like domain and in the juxtamembrane region abolished neurotrophin binding. Dose-response curves on cells expressing full-length trkA were identical for NGF and NT-3 (0.1 ng/ml-50 ng/ml) while cells expressing leucine rich motif (LRM) minus receptors required high concentrations of NT-3 (50 ng/ml). Scatchard analysis revealed a loss of high-affinity NT-3, but not NGF, binding to the LRM minus receptor consistent with the neurite dose-response curves. Moreover, cells expressing the LRM minus receptors failed to fasciculate and showed delayed arborization in comparison to cells expressing wild-type trkA, suggesting a possible role for the LRM's in neurotrophin-induced differentiation and in high-affinity NT-3 binding.

Tissue-specific alternative splicing generates two isoforms of the trkA receptor.

The trkA receptor functions as a signal transducing receptor for nerve growth factor. In this report, we show that alternative splicing results in the production of two distinct trkA isoforms in both rats and humans. These isoforms differ by virtue of a 6-amino acid insertion in their extracellular domain, the placement of which corresponds exactly with the breakpoint found in several human trkA oncogenes. When tested in fibroblasts, the presence (trkAII) or absence (trkAI) of the 6-amino acid insert does not affect the receptor's ligand binding specificity or its ability to transduce functional signals in response to nerve growth factor. In rats and humans, trkAII is the only isoform expressed within neuronal tissues at appreciable levels whereas trkAI, the form of trkA originally cloned, appears to be expressed mainly in non-neuronal tissues.

The nerve growth factor family of receptors.

The neurotrophins, of which nerve growth factor (NGF) is the best known example, support the survival and differentiation of chick embryo sensory neurons at extremely low concentrations, 10(-12) M or less. These same neurons display two different classes of neurotrophin receptors with dissociation constants of 10(-11) M and 10(-9) M, respectively, implying that only low occupancy of the higher affinity receptor is required to mediate the biological actions of the neurotrophins. Two structurally unrelated receptors have now been characterized for NGF, and one of them, p75NGFR, serves as a receptor for all the known neurotrophins. This is the receptor with a dissociation constant of 10(-9) M. The second NGF receptor is a member of the trk family of tyrosine kinase receptors, p140trkA. Other members, p145trkB and p145trkC, are receptors for brain-derived neurtrophic factor (BDNF) and neurotrophin-4 (NT-4) and neurotrophin-3 (NT-3), respectively, when assayed in fibroblasts. The specificity of neurotrophin binding to these receptors appears to be much higher in neurons than in the non-neuronal cells. The receptor p140trkA has many of the properties of the higher affinity class of NGF receptors, and is able to mediate survival and differentiation of the PC12 cell line, and cell growth and transformation in fibroblast cells. On the other hand, expression of p75NGFR in several types of cells displaying p140trkA induces a component of higher affinity NGF binding not seen in its absence. Since it is unlikely that p75NGFR and p140trkA interact at the level of the receptors, the crosstalk between receptors probably occurs through their signal transduction mechanisms.(ABSTRACT TRUNCATED AT 250 WORDS)

The rat trk protooncogene product exhibits properties characteristic of the slow nerve growth factor receptor.

Two distinct nerve growth factor receptor (NGFR) complexes are present on NGF-responsive cell types; these correspond to 100 kDa and 158 kDa for the fast (fNGFR) and the slow (sNGFR) NGFRs, respectively. Previous studies indicate that each complex is derived from a separate gene product and that the sNGFR contains tyrosine kinase activity. The cDNA encoding the fNGFR has previously been cloned. In this report, a rat trk protooncogene cDNA has been isolated from PC12 cells and Trk has been shown to bind NGF, generating a complex of 158 kDa. Characterization of NGF-Trk interactions indicates that Trk and NGF dissociate more slowly than do NGF and the fNGFR. Moreover, NGF-bound Trk is not destroyed by trypsin digestion whereas the NGF-fNGFR complex is sensitive to trypsin digestion. These observations suggest that the trk protooncogene product, expressed in the absence of the fNGFR, binds NGF with properties characteristic of the sNGFR, which was identified as the high-affinity NGFR on primary neurons and PC12 cells.

Tyrosine kinase activity coupled to the high-affinity nerve growth factor-receptor complex.

Antibodies directed against nerve growth factor (NGF) immunoprecipitate a tyrosine kinase activity from NGF-treated PC12 rat pheochromocytoma cells. Based on several criteria, this activity has been correlated with the high-affinity and not the low-affinity NGF-receptor complex. The in vitro kinase activity and the tyrosine phosphorylation of the high-affinity complex can be blocked by an agent that inhibits NGF (and not epidermal growth factor)-induced tyrosine phosphorylation in PC12 cells, as well as NGF-induced neuronal differentiation of PC12 cells. These observations suggest that the high-affinity NGF-receptor complex is a substrate of tyrosine kinase activity. Phosphorylation reactions by the complex, performed in the absence of added substrate, label a single phosphopeptide of 130-135 kDa. This observation suggests that this phosphopeptide may represent the phosphorylation of the receptor kinase or the phosphorylation of a coimmunoprecipitating substrate, and possible signal-transducing molecule, of the high-affinity NGF-receptor complex.

Molecular investigations on the high-affinity nerve growth factor receptor.

Nerve growth factor (NGF) receptors have been investigated by means of affinity labeling with 125I-NGF and chemical cross-linking. Two distinct NGF-receptor complexes are detected on PC12 cells; these correspond to 100 kd and 158 kd for the low-affinity (LNGFR) and the high-affinity (HNGFR) receptors, respectively. Interestingly, three different antibodies directed against distinct epitopes on the LNGFR immunoprecipitate the low-but not the high-affinity NGF-receptor complex. Although the identities of the signaling molecules in the HNGFR are unknown, antibodies to the src, ras, raf-1, and yes products fail to immunoprecipitate either receptor complex, suggesting that these molecules are not a part of, or tightly coupled to, either receptor type. Phosphotyrosine residues are found exclusively on the HNGFR complex, suggesting that tyrosine phosphorylation may be one of the initiating events in the NGF-induced signal transduction cascade.

A rabbit lens epithelial cell line supports expression of an exogenous crystallin gene characteristic of lens fiber cell differentiation.

Cell lines derived from the lens generally fail to maintain synthesis of crystallins in long-term culture. Here we demonstrate that the N/N1003A line of undifferentiated lens epithelial cells, derived from a newborn rabbit, does not produce detectable levels of alpha-, beta- or gamma-crystallin transcripts, yet is capable of supporting the transient expression of the mouse gamma 2-crystallin promoter, a promoter which is active only in terminally differentiated lens fiber cells in vivo. Analysis of a set of deletion constructs suggested that sequences required for activity of the mouse promoter in N/N1003A cells are similar, but not identical, to those previously shown to be essential in primary chick embryo lens explants. Therefore, these results suggest that different transcriptional factors may be capable of supporting lens-specific activity of the mouse gamma 2 promoter. In addition, this cell line, N/N1003A, should be useful for investigations on the elements regulating gamma-crystallin gene expression.