Faculty Bibliography

The role of the low-affinity neurotrophin receptor (p75NTR) in signal transduction is undefined. Nerve growth factor can activate the sphingomyelin cycle, generating the putative-lipid second messenger ceramide. In T9 glioma cells, addition of a cell-permeable ceramide analog mimicked the effects of nerve growth factor on cell growth inhibition and process formation. This signaling pathway appears to be mediated by p75NTR in T9 cells and NIH 3T3 cells overexpressing p75NTR. Expression of an epidermal growth factor receptor-p75NTR chimera in T9 cells imparted to epidermal growth factor the ability to activate the sphingomyelin cycle. These data demonstrate that p75NTR is capable of signaling independently of the trk neurotrophin receptor (p140trk) and that ceramide may be a mediator in neurotrophin biology

We have examined NGF-induced signal transduction events and neuronal differentiation in MAH cells, a neuronal progenitor cell line, in which the expression of the two NGF receptors, p140trk (Trk) and p75LNGFR (p75), has been independently manipulated. Coexpression of a large molar excess of p75 substantially enhances the NGF-induced tyrosine autophosphorylation of Trk, compared with cells expressing Trk alone. MAH cells expressing both Trk and p75 stop dividing and acquire a mature neuronal morphology more rapidly and with greater efficiency than MAH cells expressing Trk alone. These biochemical and biological influences of p75 are not observed using a mutant form of NGF that binds Trk but not p75. These data provide evidence that p75 can modulate signal transduction through Trk in a neuronal progenitor cell context and that such modulation has functional consequences for the neuronal differentiation pathway induced by NGF

Nerve growth factor (NGF) binds to two cell surface receptors, p140trk and p75NGFR, which are both expressed in responsive sensory, sympathetic, and basal forebrain cholinergic neurons. While p140trk belongs to the family of receptor tyrosine kinases, p75NGFR is a member of the TNF/Fas/CD40/CD30 family of receptors. Current views of neurotrophin receptor function have tended to interpret p140trk as the high affinity NGF-binding site. To assess if the binding of NGF to p140trk was distinguishable from binding to high affinity sites on neuronal cells, PC12 cell sublines were generated which expressed p140trk alone, or coexpressed both p140trk and p75NGFR. Kinetic analysis of 125I-NGF binding indicates that it has an unusually slow rate of association with p140trk (k + 1 = 8 x 10(5) M-1 s-1). When both p140trk and p75NGFR receptors are coexpressed, the rate of association of NGF is increased 25-fold to produce a higher affinity binding site. An increase in the rate of internalization was also observed. Since high affinity binding and internalization are believed to be prerequisite for the biological activities of NGF, these results suggest that the biological effects by NGF are derived from a novel kinetic binding site that requires the expression of both receptors. The implications of these results with respect to multisubunit polypeptide receptors are discussed

Expression of Trk protein has been documented by Northern analysis in neuroblastomas with good prognosis. To localize the expression of this protein at the cellular level within individual tumors, we adapted a recently characterized pan-Trk antibody for use in formalin fixed, paraffin-embedded tissue. We have examined a group of small round blue cell tumors occurring in children, including both high and low stage neuroblastomas, to assess the presence or absence of Trk expression and its cellular localization. Positive staining for Trk protein was observed in four of four low stage (good prognosis) neuroblastomas, five of five primitive neuroectodermal tumors/Ewing's sarcoma, five of five rhabdomyosarcomas, and no lymphomas. Within the neuroblastomas, expression of Trk protein was most striking in ganglion cells, in which positive cytoplasmic staining was demonstrated regardless of tumor stage. The latter observation may lend further insight into the pathobiology of this malignant childhood tumor

The low-affinity p75 neurotrophin receptor is believed to participate with the Trk receptor tyrosine kinase in the formation of high-affinity binding sites for nerve growth factor (NGF). To investigate the functional significance of the two NGF receptors, a truncated p75 receptor was stably expressed in PC12 rat pheochromocytoma cells, yielding cells with greatly reduced levels of wild-type p75 and normal Trk levels. Although these cells were capable of normal differentiation by NGF, very few high-affinity NGF binding sites were detected. These findings indicate that high-affinity binding may be functionally dissociated from biological responses. Furthermore, an increased responsiveness to neurotrophin 3 was observed, as manifested by increased neurite outgrowth. These results suggest that a correct ratio of p75 and p140trk is required to create high-affinity sites and that p75 expression may assist in the discrimination between related but different neurotrophin factors

The receptors for tumor necrosis factor (TNF) are represented by two transmembrane proteins, p55TNFR and p75TNFR, which are members of a family of cell surface molecules, including the Fas antigen, CD30, CD40, OX40, a Shope fibroma virus protein, and the low affinity p75 nerve growth factor receptor. A common structural feature is a sequence of 40 amino acids that is found in adjacent repeated domains, with 6 cysteine residues in a conserved register. To assess the functional significance of this cysteine-rich domain (CRD), we have constructed chimeric receptors between each TNF receptor and the low affinity nerve growth factor receptor. The chimeric receptor cDNAs were expressed efficiently in COS-1 and 3T3 fibroblasts, as assessed by affinity cross-linking, cell surface biotinylation and immunoprecipitation, and equilibrium binding. Receptors with two CRD of either TNF receptor were incapable of binding TNF, whereas receptors with all four CRD retained the ability to bind TNF with wild type affinity. These results, in conjunction with previous deletion mutation studies, suggest that TNF binding to each receptor requires all four cysteine-rich repeats. Furthermore, analysis of chimeric receptors containing domains of p55TNFR suggests that cytoplasmic sequences directly influence the levels of receptor expression