Identification of the cell surface and nuclear receptors for NGF in a breast carcinoma cell line

¹²⁵I-nerve growth factor (NGF) was found to be internalized and translocated to the nucleus of SKBr5 breast carcinoma cells. The cytoplasm and chromatin isolated from nonmitotic cells accumulated two-and five-fold, respectively, more of ¹²⁵I-NGF than the cells undergoing mitosis. MAb 20.4 developed against the NGF cell surface receptor immunoprecipitated the 80,000 M_r receptor from plasma membrane and two protein species from the chromatin; 90,000 M_r (major band) and 200,000 M_r (minor band). In SKBr5 cells, binding of NGF to the chromatin did not affect synthesis of rRNA. Proliferation of SKBr5 cells was slightly stimulated by NGF. In control melanoma A875 cells, which express the 230,000 M_r chromatin receptor, NGF inhibited both rRNA synthesis and cell proliferation. We suggest that the 90,000 M_r chromatin receptor expressed by SKBr5 cells represents a “nonactive”, ligand-binding subunit of the high molecular weight receptor for NGF. The critical role of the chromatin receptor for NGF in rRNA-dependent cell proliferation is discussed. © 1993 Wiley-Liss, Inc.     

Antagonistic effect of PDGF and NGF on transcription of ribosomal DNA and tumor cell proliferation

The molecular mechanism by which NGF and PDGF affect growth of tumor cells was tested in human melanoma WM 266-4 and colorectal carcinoma SW 707 cell lines. We present evidence that NGF translocated to the nucleus and bound to the chromatin of SW 707 cells, which express the cell surface and the chromatin receptor for NGF, inhibits ribosomal RNA synthesis which in consequence leads to inhibition of cell proliferation. In WM 266-4 cells, which do not express NGF receptor, NGF does not affect cell proliferation. In contrast, PDGF translocated to the nucleus of both SW 707 and WM 266-4 cells activates ribosomal RNA synthesis. We report here that NGF abolishes PDGF-activated ribosomal RNA synthesis and PDGF-stimulated growth of tumor cells.     

NGF synthesis and NGF receptor expression in the embryonic mouse trigeminal system

1. The development of the mouse trigeminal system is outlined and its advantages for studying the synthesis of low-abundance regulatory proteins are described. 2. The onset of NGF gene expression and NGF synthesis in the cutaneous target field of the trigeminal ganglion coincide with the arrival of the earliest nerve fibres. 3. The distribution and magnitude of NGF synthesis within the target field are related to its final innervation density. 4. NGF receptors are first detected on trigeminal neurons when their peripheral axons reach the target field. 5. Neither NGF synthesis nor NGF receptor expression are dependent on nerve-target contact but appear to occur as part of an intrinsic developmental program in the target field and neurons, respectively. 6. The time-course of NGF synthesis and NGF receptor expression indicate that NGF does not play a role in guiding axons to their target fields in development.     

Organization of the thyroid hormone receptor in the chromatin of C6 glial cells: Evidence that changes in receptor levels are not associated with changes in receptor distribution

The association of [¹²⁵I]T3-receptor complexes with C6 cell chromatin was analysed after a limited digestion with micrococcal nuclease (MN) or DNase I. Both nucleases solubilized up to 60–70% of receptor and 0.4 M KCl extracted 70%, of the non-digested receptor, thus showing that only a residual fraction of receptor is associated with the nuclear matrix. With DNase I the receptor was released 2–3-fold faster than the bulk of chromatin, whereas a preferential release of receptor over total chromatin was not observed with MN. The digestion of receptor with DNase I and MN occurred 14- and 6-fold faster, respectively, than the appearance of PCA-soluble chromatin. Preincubation for 48 h with 4 nM T3 of 2 mM butyrate significantly altered receptor levels but did not change sensitivity to the nucleases. These results suggest that the thyroid hormone receptor is associated with chromatin highly sensitive to nuclease digestion, and that changes in receptor number are not associated with changes in its distribution in chromatin.     

Expression and structure of the human NGF receptor

The nucleotide sequence for the human nerve growth factor (NGF) receptor has been determined. The 3.8 kb receptor mRNA encodes a 427 amino acid protein containing a 28 amino acid signal peptide, an extracellular domain containing four 40 amino acid repeats with six cysteine residues at conserved positions followed by a serine/threonine-rich region, a single transmembrane domain, and a 155 amino acid cytoplasmic domain. The sequence of the extracellular domain of the NGF receptor predicts a highly ordered structure containing a negatively charged region that may serve as the ligand-binding site. This domain is conserved through evolution. Transfection of a full-length cDNA in mouse fibroblasts results in stable expression of NGF receptors that are recognized by monoclonal antibodies to the human NGF receptor and that bind [125I]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.     

NGF receptor reexpression and NGF-mediated cholinergic neuronal hypertrophy in the damaged adult neostriatum

Adult cholinergic interneurons of the neostriatum are not immunoreactive for monoclonal antibody to NGF receptor, whereas the developing neostriatum is immunoreactive for this same antibody. Chronic NGF infusion into the adult neostriatum resulted in reexpression of the NGF receptor such that many cholinergic interneurons became immunoreactive for NGF receptor. NGF infusion dramatically increased the size and choline acetyltransferase immunoreactivity of these same cholinergic neurons. Additionally, in situ hybridization demonstrated an increase in the number of cells expressing NGF receptor mRNA in the NGF-infused striatum. These findings indicate that central cholinergic neurons which lose their NGF receptors during postnatal development will resume their NGF responsiveness when the tissue is damaged. Such a damage-induced mechanism may act to enhance the action of trophic factors, including NGF, released at the site of injury and enhance the responsiveness of damaged CNS neurons to exogenously administered trophic factors.     

A quantitative study of the developmental expression of nerve growth factor (NGF) receptor in rats

The developmental expression of nerve growth factor (NGF) receptor was quantitated in either homogenates or plasma membrane-enriched preparations from whole rat embryos or from isolated tissues. The assay involved crosslinking 125I-NGF to receptors followed by immunoprecipitation with a monoclonal antibody to rat NGF receptor. In some cases, the pellet was resuspended and subjected to a sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) autoradiographic analysis. The NGF receptor was found in whole embryo homogenates as early as embryonic Day 10 (E10) (earliest age examined). The NGF receptor content in whole embryos per milligram protein increased about 3-fold from E11 to E18 and decreased slightly at E20. SDS-PAGE autoradiography showed that the molecular weights of 125I-NGF-bound receptors did not vary with age. The NGF receptor content in sciatic nerve homogenates decreased 23-fold from newborn to adulthood. The change of NGF receptor level in hindleg muscle had a profile similar to that seen in sciatic nerve. The NGF receptor content in superior cervical ganglion (SCG) or dorsal root ganglion (DRG) homogenate preparations was expressed in two ways. On a per milligram protein basis, in SCG, the receptor density was decreased slightly from E20 to adulthood; in DRG, it was relatively constant from E15 through postnatal Day 0 (PND-0) and then dropped 6.7-fold in adults. On a per ganglion basis, in SCG, it increased 4.4-fold from E20 to adult; in DRG, it increased 9-fold from E15 to PND-0 and then stayed constant through adulthood. In brain membrane preparations, the NGF receptor level decreased 11-fold from E15 to adulthood. In spinal cord membrane preparations, it decreased 7-fold from E18 to adulthood. Levels of receptor in cord were always greater than in brain. These data suggest that alterations in the NGF receptor density may have a role in changes in tissue responsiveness to NGF during development.     

Nerve growth factor (NGF) receptor on rat glial cell lines. Evidence for NGF internalization via p75NGFR.

Two types of nerve growth factor (NGF) receptors have been described: high affinity (class I) and low affinity (class II). Biological responses to NGF are thought to be mediated by class I receptors, whereas the role of class II receptors is less clear. While some neuronal cells express both receptor types, only class II receptors have been detected on glial cells. Two glial cell lines, peripheral Schwannoma D6P2T and central 33B glioma cells, were employed to investigate the properties of class II receptors in the absence of class I receptors. These cell lines were found to express NGF receptors identified as class II by a low nanomolar dissociation constant, rapid dissociation kinetics at 4 degrees C, and trypsin sensitivity. The receptor was found to bind brain-derived neurotrophic factor with similar affinity as NGF. The responsible binding molecule appeared in sodium dodecyl sulfate-polyacrylamide gel electrophoresis as a heterogeneously glycosylated protein of 60-80 kDa with a tendency to aggregate. All receptor bands affinity-labeled with radioiodinated NGF were immunoprecipitated with anti-p75NGFR antibody, but not with anti-p140prototrk antiserum. In these cells, which express p75NGFR as only NGF receptor, a time- and temperature-dependent appearance of a nondisplaceable, trypsin-resistant, acid wash-stable ligand fraction, followed by an increase of trichloroacetic acid-soluble radiolabel in the medium was observed. This sequestration resembled receptor-mediated internalization with subsequent degradation of NGF. Whether this ligand processing indicates a functional role of p75NGFR in glial cells remains to be shown.     

Nerve growth factor (NGF) induces neuronal differentiation in neuroblastoma cells transfected with the NGF receptor cDNA.

Human nerve growth factor (NGF) receptor (NGFR) cDNA was transfected into a neuroblastoma cell line (HTLA 230) which does not express a functional NGF-NGFR signal transduction cascade. Short-term treatment of stably transfected cells (98-3) expressing membrane-bound NGF receptor molecules resulted in a cell cycle-dependent, transient expression of the c-fos gene upon treatment with NGF, suggesting the presence of functional high-affinity NGFR. Extensive outgrowth of neurites and cessation of DNA synthesis occurred in transfectants grown on an extracellular matrix after long-term treatment with NGF, suggesting terminal differentiation. Our data support the idea that introduction of a constitutively expressed NGFR cDNA into cells with neuronal background results in the assembly of a functional NGF-NGFR signal cascade in a permissive extracellular environment.     

Spectroscopic and chemical studies of the interaction between nerve growth factor (NGF) and the extracellular domain of the low affinity NGF receptor.

Nerve growth factor (NGF) interacts with a cell surface receptor on responsive neurons to initiate a series of cellular events leading to neuronal survival and/or differentiation. The first step in this process is the binding of NGF to a low affinity and/or a high affinity receptor. In the present report, we have studied the conformation and stability of recombinant receptor extracellular domain (RED) from the human low affinity receptor and the structural basis of its interaction with NGF. Circular dichroism (CD) studies indicate that the RED is primarily random coil in nature with little regular secondary structure. Thermal stability studies have shown that this irregular conformation is a specific structure that can undergo a reversible two-state thermal denaturation with a concomitant fluorescent and CD change. During heating at 100 degrees C for 15 min, the structure of RED is sufficiently unfolded for a reducing agent, dithiothreitol, to inactivate the receptor toward NGF binding and cross-linking. The complex formation between the RED and NGF has been examined by differential CD measurements, and we have shown that a small, reproducible change in conformation occurs in RED or NGF upon interaction. These results are interpreted in terms of the initiation of NGF cell surface binding and possible modes of signal transduction.     

The spatial and temporal pattern of beta NGF receptor expression in the developing chick embryo

To gain insight into the developmental program of nerve growth factor (NGF) receptor expression, the binding of [125I] beta NGF to frozen chick sections was investigated autorradiographically between embryonic day 3 (E3) and post-hatching day 3. Strong NGF receptor expression was observed as early as E4, throughout embryonic development and in the post-hatching period at the classical NGF target sites: the paravertebral sensory and sympathetic ganglia, the paraaortal sympathetic ganglia as well as the cranial sensory ganglia with neurons of neural crest origin and their respective nerves. Only weak [125I] beta NGF binding was observed during a restricted time span in the parasympathetic ciliary ganglion. Clear differences were observed in the intensity and in the developmental time course of [125I] beta NGF binding to the dorsomedial and ventrolateral aspects of the dorsal root ganglia. NGF receptors were also found to be expressed on central axons of the dorsal root entry zone and the dorsal tract in the spinal cord. A transient expression of specific NGF binding sites of the same high affinity as measured at the classical NGF targets, was detected in the lateral motor column and in muscle at the time of motoneuron synapse formation and elimination.     

NGF induction of NGF receptor gene expression and cholinergic neuronal hypertrophy within the basal forebrain of the adult rat

Chronic infusion of nerve growth factor (NGF) into the forebrain of the adult rat produced increases in NGF receptor (NGF-R) mRNA hybridization, NGF-R immunoreactivity, choline acetyltransferase (ChAT) mRNA hybridization, and neuronal hypertrophy, when compared with vehicle infusion or noninfused rat brain. In situ hybridization showed NGF induction of NGF-R gene expression, documented by increases in the number of NGF-R mRNA-positive cells within the medial septum, diagonal band, and nucleus basalis magnocellularis. NGF also produced hypertrophy of ChAT mRNA-positive neurons. These results suggest that NGF produces cholinergic neuronal hypertrophy through induction of NGF-R gene expression within the basal forebrain.     

Specific inhibition of NGF receptor tyrosine kinase activity by K-252a.

An involvement of protein tyrosine kinase in the transduction of the signals initiated by nerve growth factor (NGF) was investigated. A tyrosine kinase inhibitor, herbimycin, inhibited neurite outgrowth of rat pheochromocytoma PC12 cells induced by NGF but not that by dibutyryl-cAMP. Herbimycin and genistein blocked NGF-dependent activation of ras p21 whose essential function in neuronal differentiation has been reported. These observations suggested that tyrosine kinase activity is involved in the signaling pathways. K-252a, by contrast, inhibited NGF-induced but not EGF-dependent activation of ras p21. Tyrosine kinase activity of gp140trk, a constituent of NGF receptor, is activated by NGF for much a longer period compared to the activation of EGF receptor autokinase activity by EGF. We further demonstrated that autophosphorylation of gp140trk is selectively inhibited by K-252a.     

Analytical purification of the slow, high affinity NGF receptor: identification of a novel 135 kd polypeptide.

Although nerve growth factor (NGF) action is mediated by the slow, high affinity NGF receptor, little is known regarding its molecular composition or mode of action. We have used reversible chemical cross-linkers and affinity chromatography strategies to purify the slow NGF receptor covalently cross-linked to its NGF ligand. Subsequent uncoupling of the cross-links reveals that the receptor-ligand complex is composed of only a novel 135 kd polypeptide interacting with NGF. The previously characterized 85 kd fast, low affinity NGF receptor is not a component of the cross-linked slow receptor-ligand complex. This newly identified 135 kd polypeptide is either the entire slow NGF receptor, or it might be one component of a larger, multisubunit slow NGF holo-receptor.     

Mutation of tryptophan-21 in mouse nerve growth factor (NGF) affects binding to the fast NGF receptor but not induction of neurites on PC12 cells.

By using in vitro DNA mutagenesis, we replaced the tryptophan residue at position 21 in mouse nerve growth factor (NGF) with either phenylalanine, leucine or serine. Yield, biological activity, immunological reactivity and receptor binding of the recombinant proteins were determined. All three mutants were produced at considerably lower yields than wild-type NGF, with the serine mutant being undetectable. The results of competitive binding assays show that tryptophan-21 is involved in recognition of the fast NGF receptor of PC12 cells. However, specific biological activity of NGF is not altered by the replacement of tryptophan-21. Our results therefore suggest that biological activity of NGF is not directly coupled to binding to the fast NGF receptor.     

Epidermal growth factor (EGF) and monoclonal antibody to cell surface EGF receptor bind to the same chromatin receptor

Cellular uptake, nuclear translocation, and chromatin binding of epidermal growth factor (EGF) and monoclonal antibodies (MAbs) against the protein domain of the EGF surface receptor (MAb 425) and against the carbohydrate Y determinant on the EGF receptor (MAb Br 15-6A) were analyzed in cell lines that express surface EGF receptor. Both EGF and MAb 425 were translocated to the nucleus and bound in nondegraded form to the chromatin of all cells tested. MAb Br 15-6A was taken up only by SW 948 colorectal carcinoma cells which express EGF receptor whereas neither EGF nor MAb 425 was taken up by SW 707 colorectal carcinoma cells which do not express EGF receptor. MAb 425 immunoprecipitated a 230- to 250-kDa chromatin protein, which appears to be the EGF chromatin receptor. EGF was localized in a single EcoRI DNA fragment suggesting that the chromatin binding was highly specific. Binding of EGF to primarily DNase II-sensitive chromatin regions protected these regions from nuclease action. The role of growth factor binding to chromatin in neoplastic transformation is discussed.     

Nerve growth factor chromatin receptor and cell surface receptor-regulated growth of melanocytes and nevus cells.

RNA synthesis in melanocytes and nevus cells, and the proliferation of those cells in the presence of nerve growth factor (NGF) and 12-0-tetradecanoyl-phorbol-13-acetate (TPA), were found to correlate with the amount of NGF bound to the chromatin versus the total internalized NGF (n/c NGF = nuclear/cellular ration). In nevus cells and in melanocytes of the early passages (n/c NGF = 0.16-0.18), NGF slightly activated RNA synthesis but was without any effect on cell growth. At passage 5-6 of melanocytes (n/c NGF = 0.88), NGF inhibited RNA synthesis, which led to inhibition of cell growth. Removal of TPA from the culture of nevus cells resulted in increased n/c NGF ratio and in a switch from activatory to inhibitory action of NGF. The possibility that the cell surface receptor mediated the stimulatory effect of NGF and may antagonize the chromatin receptor-mediated inhibitory effect of NGF of melanocyte and nevus cell growth is discussed.