Faculty Bibliography

A family of tyrosine receptor kinases known collectively as trk receptors plays an essential role in signal transduction mediated by nerve growth factor and related neurotrophins. To localize the major trk receptors (trkA, B and C) in the developing and adult central (CNS) and peripheral (PNS) nervous system, we generated monoclonal antibodies (MAbs) to extracellular (MAbs E7, E13, E16, E21, E29) and intracellular (MAb I2) domains of human trkA fused to glutathione S-transferase. Several MAbs (E7, E13, E16) recognized glycosylated trkA (gp140trk and gp110trk) in Western blots, one MAb (E7) recognized non-glycosylated (p80trk) and glycosylated trkA in immunoprecipitation assays, and two MAbs (E13, E29) detected trkA on the cell surface of NIH3T3 cells transfected with a trkA cDNA. Although generated to trkA fusion proteins, this panel of MAbs also recognized trkB and trkC in flow cytometric studies of NIH3T3 cells transfected with trkB or trkC cDNAs. Thus, we used these pan-trk MAbs to probe selected regions of the CNS and PNS including the hippocampus, nucleus basalis of Meynert, cerebellum, spinal cord, and dorsal root ganglion (DRG) to localize trkA, B, and C receptors in the developing and adult human nervous system. These studies showed that trk receptors are expressed primarily by neurons and are detectable very early in the developing hippocampus, cerebellum, spinal cord, and DRG. Although the distribution and intensity of trk immunoreactivity changed with the progressive maturation of the CNS and PNS, immunoreactive trk receptors were detected in neurons of the adult human hippocampus, nucleus basalis of Meynert, cerebellum, spinal cord, and DRG. This first study of trk receptor proteins in the developing and adult human CNS and PNS documents the expression of these receptors in subsets of neurons throughout the developing and adult nervous system. Thus, although the expression of trk receptor proteins is developmentally regulated, the constitutive expression of these neurotrophin receptors by neurons in many regions of the adult human CNS and PNS implies that mature trk receptor-bearing neurons retain the ability to respond to neurotrophins long after terminal neuronal differentiation is complete

The receptor mechanisms mediating the retrograde axonal transport of the neurotrophins have been investigated in adult rats. We show that transport of the TrkB ligands NT-4 and BDNF to peripheral neurons is dependent on the low affinity neurotrophin receptor (LNR). Pharmacological manipulation of LNR in vivo using either an anti-LNR antibody or a soluble recombinant LNR extracellular domain completely blocked retrograde transport of NT-4 and BDNF to sensory neurons, while having minimal effects on the transport of NGF in either sensory or sympathetic neurons. Furthermore, in mice with a null mutation of LNR, the transport of NT-4 and BDNF, but not NGF, was dramatically reduced. These observations demonstrate a selective role for LNR in retrograde transport of the various neurotrophins from distinct target regions in vivo

Deletion of 58 internal amino acids from the C-terminal cytoplasmic domain of p75 human nerve growth factor receptor (hNGFR) changes its localization from apical to basolateral in transfected Madin-Darby Canine Kidney (MDCK) cells (Le Bivic, A., Sambuy, Y., Patzak, A., Patil, N., Chao, M., and Rodriguez-Boulan, E. (1991) J. Cell Biol. 115, 607-618). The mutant protein, PS-NGFR, also shows a dramatic increase in its ability to endocytose NGF and to recycle through basolateral endosomes. We report here the site-directed mutagenesis analysis of PS-NGFR to localize and characterize its basolateral and endocytic sorting signals. Both signals reside in the proximal part of the PS cytoplasmic tail, between positions 306 and 314. Transferring the cytoplasmic tail (19 residues) and transmembrane domain of a truncated PS mutant to the ectodomain of the placental alkaline phosphatase, an apical glypiated ectoenzyme, redirected it to the basolateral membrane and the endocytic compartments. A tyrosine at position 308, present in this short cytoplasmic segment, was mutated into phenylalanine or alanine. The resulting mutants were expressed predominantly on the apical membrane of MDCK cells. Their ability to endocytose NGF was reduced with the alanine mutant showing the stronger diminution. The PS mutant contains a short cytoplasmic sequence necessary both for basolateral targeting and endocytosis, and the requirement for tyrosine at position 308 is crucial for basolateral targeting.

Neurotrophins initiate their biological effects by activating members of the trk tyrosine kinase subfamily. The extracellular region of trk receptors is distinguished by several common structural features, including leucine-rich repeats, clusters of cysteine-rich domains, and two immunoglobulin-like domains. However, the receptor sequences required for ligand binding have not been localized. In order to define the domains involved in NGF binding, a series of chimeric receptors was constructed using cDNA sequences from rat trkA and trkB. The chimeric constructs were expressed after transient transfection in 293 cells and the expression of each receptor was verified by immunoprecipitation and immunoblot analysis. Equilibrium binding of transfected cells revealed that the two IgG domains of trkA are essential for NGF binding. The requirement for the two IgG domains was further confirmed by Scatchard analysis and affinity crosslinking with 125I-NGF. These results indicate that NGF binding is crucially dependent upon interactions with the IgG domains of the trkA receptor

Nerve growth factor binds independently to two transmembrane receptors, the p75 neurotrophin receptor and the p140trk (trkA) tyrosine kinase receptor, which are both co-expressed in the majority of neuronal cells that respond to NGF. Previous findings have suggested that appropriate co-expression of the two receptors gives rise to high affinity NGF binding sites and increased neurotrophin responsiveness; however, evidence demonstrating a direct interaction between the two receptors in cell lines has been lacking. Here we have utilized affinity crosslinking agents with 125I-NGF to detect an association of trkA and p75 receptors in embryonic spinal cord and brain tissues enriched in the two receptors. Although multimeric complexes of trkA and p75 were not detected by affinity crosslinking, immunoprecipitation of cross-linked NGF-receptor complexes with trk-specific antibodies resulted in selective immunoprecipitation of crosslinked p75. Our results indicate that the trkA and p75 receptors can potentially interact, and that such an association may be responsible for the generation of high affinity NGF binding sites

Tumor necrosis factor (TNF-alpha) interacts with two transmembrane receptor proteins, p55TNFR and p75TNFR, which are members of a family of cell surface molecules that include the Fas antigen, CD27, CD30, CD40, OX40, a Shope fibroma viral protein, and the low-affinity p75 neurotrophin receptor. Although the p55 TNF receptor has been shown to be primarily responsible for the biologic responses of TNF-alpha, the exact involvement of the p75 TNF receptor in signaling events is unclear. Here we show that expression of a human cDNA clone for p75 in COS-1 and 3T3 cells results in the constitutive activation of an TNF-inducible NF-kappa B-containing promoter. Analysis of a number of chimeric p75 receptor cDNA constructs further suggests that this activity requires the cytoplasmic domain of the p75 receptor. These results therefore indicate that the p75 TNF receptor is capable of mediating signal transduction

The p75 neurotrophin receptor serves as a receptor for all known neurotrophins, including NGF, BDNF, NT-3, and NT-4/5. The expression pattern of p75 is known to be widespread and extends outside the nervous system, suggesting that neurotrophins may have functions beyond neuronal cell survival and differentiation. To investigate the expression of p75, a human minigene was constructed that contained the full-length receptor cDNA directed by its own promoter and 4 kb of 5' upstream sequence. This minigene was used to generate transgenic mice and was found to be expressed in selective neuronal populations such as the cerebellar external granular layer. Expression of the transgene was not observed in sensory or sympathetic ganglia or in the basal forebrain. Transection of the sciatic nerve revealed that the human transgene was appropriately upregulated after nerve injury, indicating that sequences responsible for proper induction during nerve regeneration reside in the minigene construct. In contrast, the p75 transgene was found to be extensively expressed in mesenchymal cells during development, closely mimicking the in vivo pattern of expression. The detection of p75 receptors in the mesenchyme implies that neurotrophins are likely to exert effects during morphogenesis of mesodermal tissues and that separate signals are likely to direct neuronal versus nonneuronal expression of the p75 gene

Nerve growth factor (NGF) is a neurotrophic protein essential for the maintenance and growth of peripheral sympathetic neurons and basal forebrain cholinergic neurons. Recently, NGF has also been shown to have effects on cells of the immune system. In a search for extra neural sources of NGF, we detected NGF-specific mRNA in mouse T lymphocytes of both the CD4+ and CD8+ phenotypes with the use of an RNase protection assay, PCR, and DNA sequence analysis. In CD4+ cells, NGF was present in both Th1 and Th2 Ag-specific clones, but an increase of NGF-specific message was detected after antigenic stimulation only in Th2 clones. NGF mRNA was also detected in splenic B lymphocytes and in a cell line derived from a murine follicular center cell lymphoma. Translation into protein and secretion of NGF were demonstrated by Western blot analysis. The secreted NGF is in an active form capable of inducing differentiation of PC12 cells into sympathetic-like neurons. Furthermore, conditioned medium from clones or lines positive for NGF mRNA was capable of inducing p140 tyrosine kinase autophosphorylation in 3T3 fibroblasts transfected with cDNA encoding for the tyrosine kinase family NGF receptor. We conclude that lymphocytes synthesize and secrete NGF either as a para-autocrine factor acting on the immune system itself, or as a factor for the maintenance of peripheral neurons

The low-affinity p75 molecule and trk tyrosine kinases serve as receptors for target-derived neurotrophins. While the mechanism by which receptor tyrosine kinases impart intracellular signaling has become well understood, the precise roles of the p75 receptor are not fully defined. The p75 neurotrophin receptor belongs to a family of transmembrane molecules which also serve as receptors for the tumor necrosis factor family of cytokines. Each receptor shares a common extracellular structure highlighted by conserved cysteine-rich repeats. Because NGF, BDNF, NT-3, and NT-4/5 bind to p75 with similar affinity, p75 may either act as a common subunit in a neurotrophin receptor complex with trk family members, or act by independent mechanisms to mediate biological actions of each neurotrophin