Gene transfer of truncated NGF receptor clones leads to cell surface expression in mouse fibroblasts

Antagonistic effects of c-myc and Epstein-Barr virus latent genes on the phenotype of human B cells

Epstein-Barr virus (EBV) immortalized cells and Burkitt lymphoma cells have a completely different growth pattern and phenotype. EBV immortalized cells express a set of 11 viral genes to accommodate B cell activation and proliferation, whereas EBV-positive Burkitt lymphoma cells highly express the c-myc oncogene that is activated through translocation into 1 of the immunoglobulin loci and EBNA1 as the only viral protein. We have developed a primary human B cell line conditionally immortalized by Epstein-Barr virus in which the viral gene program responsible for the induction of proliferation can be switched on and off by the addition or withdrawal of estrogen (cell line EREB2-5). Starting from this cell line we have generated 2 daughter cell lines that proliferate in a c-myc dependent fashion, 1 with a highly active exogenous c-myc gene (cell line A1) and 1 with a regulatable c-myc gene that can be switched on by withdrawal and switched off by addition of tetracycline (cell line P493-6). The comparison of the 3 cell lines has allowed us to dissect the contribution of c-myc and EBV genes to the regulation of the growth pattern and expression of cell surface molecules. We show that MYC and EBNA2 (and their respective target genes) have opposing effects on the expression of several surface markers involved in B cell activation. We show that MYC contributes to the phenotype of Burkitt lymphoma cells by upregulating CD10 and CD38 and downregulating activation markers. The phenotype of the cells is determined on one hand by the absence of the viral gene products EBNA2 and LMP1 that mediate the phenotype of activated lymphoblasts and to a lesser extent by an active contribution of the c-myc gene.

Modeled structure of the 75-kDa neurotrophin receptor

Motifs in ligand-binding domains of the neurotrophin (NTR) and lymphotoxin (TNFR-I) receptors define a family of receptors that mediates programmed cell death. We have explored relationships of architecture and function in this family through a molecular model of NTR, also called p75NGFR or LANR. Modeling by homology took advantage of four modular subdomains in the crystal structure of TNFR-I that also occur in NTR. Hypothetical complexes between the model and a ligand structure (for nerve growth factor, NGF) were then examined using docking software. NTR appears to bind in the dimer interface of NGF, making two sets of contacts. NTR subdomains III and IV provide the ligand-contact surfaces, in contrast to TNFR, in which subdomains II and III contact TNF-beta. NTR subdomain II appears to have been evolutionarily modified, potentially contributing to an interface between receptor subunits. These and other specific predictions of the model will require experimental confirmation.

p140trk mRNA marks NGF-responsive forebrain neurons: evidence that trk gene expression is induced by NGF

Nerve growth factor (NGF) appears to act as a neurotrophic factor for basal forebrain and caudate-putamen cholinergic neurons. The mechanism by which NGF transduces its signal in these neurons is yet to be defined. Recent data indicate that the product of the trk gene, p140trk, is a critical component of the NGF receptor. Herein, we show that p140trk mRNA is highly restricted in its distribution in the adult rat forebrain, that it is present in cholinergic neurons, and that most if not all cholinergic neurons contain p140trk mRNA. Furthermore, induction of trk expression by NGF suggests that neurotrophin-mediated up-regulation of their receptor tyrosine kinases is an important feature of their actions and that neurotrophins may regulate the activity of responsive neurons through increasing the level of their receptors.

Molecular approaches to nerve regeneration

Current research into regeneration of the nervous system has focused on defining the molecular events that occur during regeneration. One well-characterized system for studying nerve regeneration is the sciatic nerve of rat. Numerous studies have characterized the sequence of events that occur after a crush injury to the sciatic nerve (Cajal 1928; Hall 1989). These events include axon and myelin breakdown, changes in the permeability of the blood vessels, proliferation of Schwann cells, invasion of macrophages, and the phagocytosis of myelin fragments by Schwann cells and macrophages. The distal segment of the injured sciatic nerve provides a supportive environment for the regeneration of the nerve fibres (Cajal 1928; David & Aguayo 1981). Within a period of weeks, the injured sciatic nerve is able to regrow and successfully reinnervate the appropriate targets. Some of the molecules that provide trophic support for the regrowing nerve fibres have been identified, including nerve growth factor (NGF) (Heumann et al. 1987) and glial maturation factor beta (Bosch et al. 1989). Another class of molecules show changes in their rates of synthesis during regeneration, including both proteins (Skene & Shooter 1983; Muller et al. 1986) and mRNA species (Trapp et al. 1988; Meier et al. 1989). To better understand nerve regeneration, we have taken two, parallel molecular approaches to study the events associated with regeneration. The first of these is to study in detail the mechanism of action of a molecule that has been implicated in the regeneration process, nerve growth factor. The second approach is to identify novel gene sequences which are regulated during regeneration.(ABSTRACT TRUNCATED AT 250 WORDS)

Nerve growth factor binding domain of the nerve growth factor receptor

A structural analysis of the rat low-affinity nerve growth factor (NGF) receptor was undertaken to define the NGF binding domain. Mutant NGF receptor DNA constructs were expressed in mouse fibroblasts or COS cells, and the ability of the mutant receptor to bind NGF was assayed. In the first mutant, all but 16 amino acid residues of the intracellular domain of the receptor were removed. This receptor bound NGF with a Kd comparable to that of the wild-type receptor. A second mutant contained only the four cysteine-rich sequences from the extracellular portion of the protein. This mutant was expressed in COS cells and the resultant protein was a secreted soluble form of the receptor that was able to bind NGF. Two N-terminal deletions, in which either the first cysteine-rich sequence of the first and part of the second cysteine-rich sequences were removed, bound NGF. However, a mutant lacking all four cysteine-rich sequences was unable to bind NGF. These results show that the four cysteine-rich sequences of the NGF receptor contain the NGF binding domain.

Human central nervous system primitive neuroectodermal tumor expressing nerve growth factor receptors: CHP707m

A primitive neuroectodermal tumor (PNET) presented as a cerebral hemispheric mass in a 33-year-old man. Bone marrow metastases were discovered 11 months later. A cell line (CHP707m) was derived from these metastases. In culture, the cells showed features of neuronal differentiation, forming short neurites and synthesizing low-molecular-weight neurofilament protein. Northern blotting showed the tumor cells express nerve growth factor (NGF) receptor messenger RNA, and fluorescence-activated cell-sorting demonstrated NGF receptors on the cell surface. Western blotting showed CHP707m NGF receptors are truncated. The receptors are functional; they bind iodine 125-labeled mouse NGF with an affinity of 1.6 x 10(-9) M, and short-term treatment with NGF induces expression by the tumor cells of the proto-oncogene, c-fos. Although CHP707m is the first central nervous system PNET cell line proven to express NGF receptors, immunohistological survey of tissue sections prepared from human central nervous system PNETs showed that 13 of 35 contained NGF receptor-positive tumor cells. Thus, more than one-third of such tumors might be responsive to the effects of NGF.

Structure and developmental expression of the chicken NGF receptor

The nucleotide and deduced amino acid sequence of a cDNA clone of the chicken NGF receptor (NGFR) is reported and is compared with sequences of mammalian NGF receptors. A model is presented in which monodentate or bidentate binding of NGF dimers to repeated cysteine-rich sequence elements of the receptor yields low- or high-affinity NGF binding, respectively. In situ hybridization is used to characterize expression of NGFR in developing chick from 40 hr to 10 days of embryogenesis. NGFR mRNA expression is detected in premigratory neural crest cells, in epibranchial placode cells, and in all sensory, sympathetic and parasympathetic derivatives of these structures. In the embryonic CNS, NGFR mRNA is detected in the mantle zone but not the periventricular germinal zone throughout most of the neural tube. By Embryonic Day 8, NGFR mRNA is detected in a substantial fraction of cells in every brain region, with highest levels present in developing motor neurons. NGFR mRNA also is transiently expressed in many mesenchymal cell populations including cells in branchial arch, sclerotome, muscle anlagen, and feather follicles. The functional significance of wide-spread embryonic expression of the NGF receptor is discussed.