Expression of Nerve Growth Factor and Nerve Growth Factor Receptor Genes in Human Tissues and in Prostatic Adenocarcinoma Cell Lines

Nerve growth factor (NGF) mRNAs were detected and quantified in a variety of normal and neoplastic human tissues by northern blot hybridization. Human heart contained the highest NGF mRNA levels, whereas lower but comparable levels were found in the placenta, prostate, and kidney. All tissues examined coexpressed the low-affinity NGF receptor (LNGFR), whereas none of these tissues expressed the high-affinity NGF receptor encoded by the trk protooncogene. The widespread distribution of the LNGFR suggests that it plays a role in the regulation of normal cell growth. No overexpression of NGF or LNGFR mRNA was detected in neoplastic tissues, whereas LNGFR-like immunoreactivity was localized outside of tumor cells. Transforming growth factor-alpha and protooncogene c-fos expression in these tissues did not show a systematic correlation with NGF/LNGFR expression. Furthermore, regulation of the human NGF gene was studied in DU145 cells, a prostatic adenocarcinoma cell line that synthesizes significant NGF mRNA levels. Serum induced, whereas dexamethasone inhibited, NGF mRNA synthesis in these cells. Serum induction was preceded by a rapid and transient activation of the c-fos protooncogene.     

p75 and TrkA Receptor Signaling Independently Regulate Amyloid Precursor Protein mRNA Expression, Isoform Composition, and Protein Secretion in PC12 Cells

Abstract: The pheochromocytoma PC12 cell line was used as a model system to characterize the role of the p75 neurotrophin receptor (p75^NTR) and tyrosine kinase (Trk) A nerve growth factor (NGF) receptors on amyloid precursor protein (APP) expression and processing. NGF increased in a dose-dependent fashion neurite outgrowth, APP mRNA expression, and APP secretion with maximal effects at concentrations known to saturate TrkA receptor binding. Displacement of NGF binding to p75^NTR by addition of an excess of brain-derived neurotrophic factor abolished NGF's effects on neurite outgrowth and APP metabolism, whereas addition of brain-derived neurotrophic factor alone did not induce neurite outgrowth or affect APP mRNA or protein processing. However, treatment of PC12 cells with C2-ceramide, an analogue of ceramide, the endogenous product produced by the activity of p75^NTR-activated sphingomyelinase, mimicked the effects of NGF on cell morphology and stimulation of both APP mRNA levels and APP secretion. Specific stimulation of TrkA receptors by receptor cross-linking, on the other hand, selectively stimulated neurite outgrowth and APP secretion but not APP mRNA levels, which were decreased. These findings demonstrate that in PC12 cells expressing p75^NTR and TrkA receptors, binding of NGF to the p75^NTR is required to mediate NGF effects on cell morphology and APP metabolism. Furthermore, our data are consistent with NGF having specific effects on p75^NTR not shared with other neurotrophins. Lastly, we have shown that specific activation of TrkA receptors—in contrast to p75^NTR-associated signaling—stimulates neurite outgrowth and increases nonamyloidogenic secretory APP processing without increases in APP mRNA levels.     

Differential expression of mRNAs for neurotrophins and their receptors after axotomy of the sciatic nerve

The neurotrophin family includes NGF, brain-derived neurotrophic factor (BDNF), neurotrophin-3 (NT-3), and neurotrophin-4 (NT-4). Previous studies have demonstrated that expression of NGF and its low-affinity receptor is induced in nonneuronal cells of the distal segment of the transected sciatic nerve suggesting a role for NGF during axonal regeneration (Johnson, E. M., M. Taniuchi, and P. S. DeStefano. 1988. Trends Neurosci. 11:299-304). To assess the role of the other neurotrophins and the members of the family of Trk signaling neurotrophin receptors, we have here quantified the levels of mRNAs for BDNF, NT-3, and NT-4 as well as mRNAs for trkA, trkB, and trkC at different times after transection of the sciatic nerve in adult rats. A marked increase of BDNF and NT-4 mRNAs in the distal segment of the sciatic nerve was seen 2 wk after the lesion. The increase in BDNF mRNA was mediated by a selective activation of the BDNF exon IV promoter and adrenalectomy attenuated this increase by 50%. NT-3 mRNA, on the other hand, decreased shortly after the transection but returned to control levels 2 wk later. In Schwann cells ensheathing the sciatic nerve, only trkB mRNA encoding truncated TrkB receptors was detected with reduced levels in the distal part of the lesioned nerve. Similar results were seen using a probe that detects all forms of trkC mRNA. In the denervated gastrocnemius muscle, the level of BDNF mRNA increased, NT-3 mRNA did not change, while NT-4 mRNA decreased. In the spinal cord, only small changes were seen in the levels of neutrophin and trk mRNAs. These results show that expression of mRNAs for neurotrophins and their Trk receptors is differentially regulated after a peripheral nerve injury. Based on these results a model is presented for how the different neurotrophins could cooperate to promote regeneration of injured peripheral nerves.     

On the role of Trk1 and Trk2 in Schizosaccharomyces pombe under different ion stress conditions

Trk1 and Trk2 are the major K(+) transport systems in Schizosaccharomyces pombe. Both transporters individually seem to be able to cope with K(+) requirements of the cells under normal conditions, since only the double mutant shows defective K(+) transport and defective growth at limiting K(+) concentrations. We have studied in detail the role of SpTrk1 and SpTrk2 under different ion stress conditions. Results show that the strain with only Trk1 (trk1(+)) is less sensitive to Li(+) and to hygromycin B, it grows better at low K(+) and it survives longer in a medium without K(+) than the strain expressing only Trk2 (trk2(+)). We conclude that Trk1 contributes more efficiently than Trk2 to the performance of the fission yeast under ion stress conditions. In the wild type both trk1(+) and trk2(+) genes are expressed and probably collaborate for the performance of the cells.     

Level of p75 receptor expression in sensory ganglia is modulated by NGF level in the target tissue

Neurotrophins play an essential role in sensory development by providing trophic support to neurons that innervate peripheral targets. Nerve growth factor (NGF), neurotrophin-3, neurotrophin-4, and brain-derived neurotrophin exert their survival effect by binding to two transmembrane receptor types: trk receptors, which exhibit binding specificity, and the p75^NTR receptor, which binds all neurotrophins. To determine how target-derived neurotrophins affect sensory neuron development and function, we used transgenic mice that overexpress NGF in the skin to examine the impact of NGF overexpression on receptor expression. Previous studies of trk expression in trigeminal ganglia of adult NGF transgenics showed that the percentage of trkA neurons doubled and their number increased fivefold. The present study focused on the p75 receptor and shows that the percentage of neurons expressing p75^NTR also increase in NGF ganglia, but only by 10%. This increase did not encompass the small, BS-IB-4 isolectin-positive cells as they remained p75 negative in transgenic ganglia. Interestingly, levels of trkA protein were not increased on a per-cell level, whereas levels of p75^NTR increased nearly threefold. These results show that in sensory systems, target-derived NGF modulates the level of p75^NTR receptor expression, and in so doing, may act to regulate the formation of functional receptor complexes and subsequent trophic action. © 1998 John Wiley & Sons, Inc. J Neurobiol 35: 258–270, 1998     

p75NTR: A study in contrasts

The p75 neurotrophin receptor (p75NTR) and trkA, trkB and trkC mediate the physiological effects of the neurotrophins. The trk receptors are responsible for the stereotypical survival and growth properties of the neurotrophins but defining the physiological function of the p75NTR has proven difficult. The p75NTR binds each of the neurotrophins with low nanomolar affinity whereas the three trk receptors show strong binding preferences for individual neurotrophins; in some cell types, p75NTR is the only neurotrophin receptor whereas in others it is co-expressed with the trks. The analysis of p75NTR function has been complicated by the fact that the predominant physiological role of p75NTR changes dramatically depending on cell context. Available data suggests that in cells where p75NTR is co-expressed with trk receptors, p75NTR functionally collaborates with the trks to either enhance responses to preferred trk ligands, to reduce neurotrophin-mediated trk receptor activation resulting from non-preferred ligands or to facilitate apoptosis resulting from neurotrophin withdrawal. In cells lacking trk expression, p75NTR can act autonomously to activate ligand-dependent signaling cascades that may in some circumstances result in apoptosis but probably not through pathways utilized by its apoptotic brethren in the TNF receptor superfamily. Potential mechanisms for each of these functions of p75NTR are considered and the physiological implications of this unique signaling system are discussed.     

Signaling of the neurotrophin receptor p75 in relation to Alzheimer’s disease

The cellular mechanism of neuronal apoptosis in Alzheimer’s disease (AD) is poorly understood. Many hypotheses have been put fourth to explain the underlying reason for neuro-degeneration in AD. Here, it is demonstrated that all neurotrophins that activated p75, without co-activation of the relevant Trk co-receptor, mediated apoptosis in hippocampal neurons. Thus, proneurotrophins and amyloid β peptides (Aβ) can induce p75-mediated apoptosis in hippocampal neurons since they do not bind or activate Trk receptors. Based on the combined effects of aging, proneurotrophins, neurotrophins, and Aβ, a novel model of pathogenesis in AD is proposed. This mini-review explores the ligand and cell type based signaling pathways of the neurotrophin receptor p75 relating to Alzheimer’s disease.     

The non-peptidyl fungal metabolite L-783,281 activates TRK neurotrophin receptors

Neurotrophin binding to the extracellular surface of the Trk family of tyrosine kinase receptors leads to the activation of multiple signalling cascades, culminating in neuroregenerative effects, including neuronal survival and neurite outgrowth. Since neurotrophins themselves are not ideal drug candidates due to their poor pharmacokinetic behaviour and bioavailability, small molecule neurotrophin mimetics may be beneficial in treating a number of neurodegenerative disorders. The present study demonstrates that L-783,281, a non-peptidyl fungal metabolite, is capable of stimulating TrkA, B and C phosphorylation to various extents in CHO cells stably expressing human Trk receptors. L-783,281 also stimulated Trk phosphorylation in a number of rat and human primary neuronal cultures, whereas the highly similar compound, L-767,827, was without effect. Mechanistic studies utilizing transiently transfected PDGF/TrkA and TrkA/PDGF chimeras, demonstrated that L-783,281 is likely to interact with the intracellular domain of the TrkA receptor. Further investigations suggested that L-783,281 was nevertheless able to instigate receptor dimerization by binding in a non-covalent manner. Although the cytotoxicity of the compound was shown to preclude its effects in neuronal survival and neurite outgrowth assays, it is a prototype for a small molecule neurotrophin mimetic that activates Trk by interacting at a site different from the neurotrophin-binding site.     

Neurotrophin receptor expression in retrogradely labeled trigeminal nociceptors—comparisons with spinal nociceptors

In situ hybridization for trk A mRNA in trigeminal ganglion neurons retrogradely labeled with FluoroGold from the mandibular incisor demonstrated limited expression of the high-affinity nerve growth factor (NGF) receptor in this presumptive nociceptor population. Immunocytochemistry using polyclonal anti- trk A antibodies confirmed this result and extended it to show low levels of trk A protein expression in afferents labeled from the cornea. Less than 10% of the cells innervating the incisor, and ~15% of those innervating the cornea, were trk A-positive in adult and neonatal mice. This proportion is considerably lower than that observed in Dorsal Root Ganglion nociceptors, in which ~80% in neonates and ~40% in adults express trk A (Molliver and Snider, J Comp Neurol 381: 428-438, 1997). Presumptive trigeminal nociceptors were further identified on the basis of expression of Calcitonin gene related peptide. In the entire ganglion, ~43% of the trk A-positive cells were CGRP-positive, and ~44% of the CGRP-positive cells were trk A-positive. Most trk A-positive cells that were CGRP-negative were medium-to-large diameter, while most of those that were CGRP-positive but trk A-negative were small diameter. Only ~5% of trk A-positive cells labeled from the incisor, and ~10% from the cornea, were CGRP-positive. Approximately 15% of the corneal or pulpal afferent neurons expressed ret -immunoreactivity. These results suggest that trigeminal nociceptors differ from spinal nociceptors in several significant ways. Differences in neurotrophic requirements may be related to differences in target tissues, in embryonic origin of some trigeminal ganglion cells, or in the timing of down-regulation of trk A expression in trigeminal ganglion cells.     

Expression of neurotrophins and Trk receptors in the developing,adult, and regenerating avian cochlea

We studied the expression of neurotrophins and their Trk receptors in the chicken cochlea. Based on in situ hybridization, brain-derived neurotrophic factor (BDNF) is the major neurotrophin there, in contrast to the mammalian cochlea, where neurotrophin-3 (NT-3) predominates. NT-3 mRNA labeling was weak and found only during a short time period in the early cochles. During embryogenesis, BDNF mRNA was first seen in early differentiating hair cells. Afferent cochlear neurons expressed trkB mRNA from the early stages of gangliogenesis onward. In accordance, in vitro, BDNF promoted survival of dissociated neurons and stimulated neuritogenesis from ganglionic explants. High levels of BDNF mRNA in hair cells and trkB mRNA in cochlear neurons persisted in the mature cochlea. In addition, mRNA for the truncated TrkB receptor was expressed in nonneuronal cells, specifically in supporting cells, located adjacent to the site of BDNF synthesis and nerve endings. Following acoustic trauma, regenerated hair cells acquired BDNF mRNA expression at early stages of differentiation. Truncated trkB mRNA was lost from supporting cells that regenerated into hair cells. High levels of BDNF mRNA persisted in surviving hair cells and trkB mRNA in cochlear neurons after noise exposure. These results suggest that in the avian cochlea, peripheral target-derived BDNF contributes to the onset and maintenance of hearing function by supporting neuronal survival and regulating the (re)innervation process. Truncated TrkB receptors may regulate the BDNF concentration available to neurites, and they might have an important role during reinnervation. © 1997 John Wiley & Sons, Inc. J Neurobiol 33: 1019–1033, 1997     

p75 Neurotrophin receptor mediates neurotrophin activation of NF‐kappa B and induction of iNOS expression in P19 neurons

P19 embryonic carcinoma cells can be differentiated into neurons that form synaptic connections and that produce a variety of neurotransmitters. Results of RT‐PCR indicate that P19 neurons express several neurotrophin receptors (p75^NTR, trkB, and trkC, but not trkA) but they do not express any of the four neurotrophins. Consistent with the presence of trkB but not trkA, BDNF causes rapid phosphorylation of MAP kinases ERK1 and ERK2, but NGF does not. Neurotrophins induce translocation of NF‐κB into the nucleus. All four neurotrophins induce activation of NF‐κB in a biphasic manner. This effect is apparently mediated by p75^NTR, because an inhibitor of trk receptors, K252a, does not inhibit activation of NF‐κB. Instead, K252a itself promotes activation of NF‐κB and this effect is additive with the effect of neurotrophins. Inhibition of reactive oxygen intermediates with PDTC completely abolishes basal activity of NF‐κB and strongly inhibits activation of NF‐κB by neurotrophins, indicating an important role of reactive oxygen intermediates in the pathway by which neurotrophins activate NF‐κB. NF‐κB is known to promote expression of the iNOS gene. We found that all four neurotrophins increased iNOS mRNA levels, resulting in increased accumulation of iNOS protein. In contrast, none of the neurotrophins stimulated nNOS mRNA or protein synthesis. PDTC abolishes constitutive and neurotrophin‐induced expression of iNOS mRNA and protein and abolishes constitutive expression of nNOS mRNA, suggesting that reactive oxygen intermediates promote expression of nNOS. © 2003 Wiley Periodicals, Inc. J Neurobiol 55: 191–203, 2003     

p75NTR-mediated signaling promotes the survival of myoblasts and influences muscle strength

During muscle development, the p75(NTR) is expressed transiently on myoblasts. The temporal expression pattern of the receptor raises the possibility that the receptor is influencing muscle development. To test this hypothesis, p75(NTR)-deficient mutant mice were tested for muscle strength by using a standard wire gripe strength test and were found to have significantly decreased strength relative to that of normal mice. When normal mybolasts were examined in vivo for expression of NGF receptors, p75(NTR) was detected on myoblasts but the high affinity NGF receptor, trk A, was not co-expressed with p75(NTR). In vitro, proliferating C2C12 and primary myoblasts co-expressed the p75(NTR) and MyoD, but immunofluorescent analysis of primary myoblasts and RT-PCR analysis of C2C12 mRNA revealed that myoblasts were devoid of trk A. In contrast to the cell death functions that characterize the p75(NTR) in neurons, p75(NTR)-positive primary and C2C12 myoblasts did not differentiate or undergo apoptosis in response to neurotrophins. Rather, myoblasts survived and even proliferated when grown at subconfluent densities in the presence of the neurotrophins. Furthermore, when myoblasts treated with NGF were lysed and immunoprecipitated with antibodies against phosphorylated I-kappaB and AKT, the cells contained increased levels of both phospho-proteins, both of which promote cell survival. By contrast, neurotrophin-treated myoblasts did not induce phosphorylation of Map Kinase p42/44 or p38, indicating the survival was not mediated by the trk A receptor. Taken together, the data indicate that the p75(NTR) mediates survival of myoblasts prior to differentiation and that the activity of this receptor during myogenesis is important for developing muscle.     

Structure–function relationships in the neurotrophin family

The study of structure–function relationships in the neurotrophin family has in recent years increased our understanding of several important aspects of neurotrophin function. Site-directed mutagenesis studies have localized amino acid residues important for binding to the low-affinity (p75^LNGFR), as well as to the members of the Trk family of tyrosine kinase receptors. A cluster of positively charged residues has been shown to form a surface for binding to p75^LNGFR in all four neurotrophins. Differences in the spatial distribution of these charges among the different neurotrophins may explain some of their distinct binding properties. Elimination of these positive charges drastically reduces binding to P75^LNGFR but not to the Trk family members, and it does not impair the biological properties of the neurotrophins in vitro, arguing that binding to and activation of Trk receptors is sufficient to mediate the biological responses of neurotrophins. In contrast. the binding sites to Trk receptors appear to be formed by discontinuous stretches of amino acid residues distributed throughout the primary sequence of the molecule. These include the N-terminus, some of the variable loop regions and a β-strand. Despite their apparent distribution, when viewed in the three-dimensional structure of NGF, these residues appear grouped on one side of the neurotrophin dimer, delineating a continuous surface extending approximately parallel to the twofold symmetry axis of the molecule. Two symmetrical surfaces are formed along the axis of the neurotrophin dimer providing a model for ligand-mediated receptor dimerization. In the neurotrophin family, co-evolution of cognate ligands and Trk receptors has developed specific contacts through different residues in the same variable regions of the neurotrophins. Thus, binding specificity is determined by the cooperation of distinct active and inhibitory binding determinants that restrict ligand-receptors interactions. Binding determinants to the Trk receptors can be manipulated independently in a rational fashion to create neurotrophin analogues with novel ligand-binding properties. In this way, second-generation chimeric neurotrophins with multiple specificities (pan-neurotrophins) have been engineered which may have valuable applications in the treatment of neurodegeneration and nerve damage. 1994 John Wiley & Sons, Inc.     

Spatiotemporal patterns of expression of neurotrophins and neurotrophin receptors in mice suggest functional roles in testicular and epididymal morphogenesis.

Several reports have established that the action of neurotrophins is not restricted to the nervous system but can affect a broad range of non-neuronal cells. Nerve growth factor (NGF) is present in adult testis and has been suggested as a potential regulator of meiosis in rat seminiferous epithelium. Here we present an extensive immunohistochemical study on neurotrophins and their receptors (p75 and trk) in the developing mouse testis and epididymis, and in fetal human testis. During the early steps of testicular and epididymal organization in the mouse, strong p75 immunoreactivity is detectable in the gonadal ridge in the mesenchyme that is excluded from the evolving testicular cords, and in the mesenchymal cells of the mesonephros. Later in organogenesis, most of the p75-positive interstitial cells of the testis coexpress neurotrophin-3 (NT-3) and the truncated trk B receptor in a developmentally regulated pattern. Our Western blot data confirm the expression of these molecules. These findings suggest that neurotrophin receptors play a role in early inductive events during critical periods of testicular and epididymal development. During fetal and postnatal histogenesis, an increasing number of NT-3- and p75-positive mesenchymal cells start to express alpha-smooth muscle isoactin, suggesting a role for the so-called neurotrophic system in the differentiation of testicular myoid cells and epididymal smooth muscle cells. In the testis of an 18-wk gestational-age human fetus, immunohistochemical analysis has shown intense immunoreactivity of mesenchymal cells to antibodies for neurotrophin receptors p75, trk A, and trk C, and their ligands NGF and NT-3. In addition, we found that in the human fetal testis, the interstitial cells that are differentiating into peritubular myoid cells are associated with a dense network of nerve fibers. Our data suggest that neurotrophins and their receptors are involved in a multifunctional system that regulates cell differentiation and innervation in the developing testis and epididymis.     

Neurotrophins and lung disease

Neurotrophins are growth factors that exert multiple actions on neuronal and nonneuronal cells. Neurotrophin receptors are expressed on central and peripheral neurons, lymphocytes, monocytes, mast cells, and fibroblasts. In accordance with the distribution of their receptors, neurotrophins control the development and function of neurons and regulate inflammatory processes. Production of neurotrophins is altered in asthma, lung cancer, and pulmonary fibrosis. Evidence from animal models has implicated nerve growth factor (NGF) as a mediator of pulmonary inflammation, bronchoconstriction, and airway hyperreactivity, all of which are hallmarks of asthma. NGF regulates the growth of lung tumor cells and cultured lung fibroblasts. Thus neurotrophins, particularly NGF, are candidate molecules for regulating disease processes in asthma, lung cancer, and pulmonary fibrosis.     

Expression of the neurotrophin receptors Trk A and Trk B in adult human astrocytoma and glioblastoma

Neurotrophins and their receptors of the Trk family play a critical role in proliferation, differentiation and survival of the developing neurons. There are reports on their expression in neoplasms too, namely, the primitive neuroectodermal tumours of childhood, and in adult astrocytic gliomas. The involvement of Trk receptors in tumour pathogenesis, if any, is not known. With this end in view, the present study has examined 10 tumour biopsy samples (identified as astrocytoma, pilocytic astrocytoma and glioblastoma) and peritumoral brain tissue of adult patients, for the presence of Trk A and Trk B receptors, by immunohistochemistry. The nature of the tumour samples was also confirmed by their immunoreactivity (IR) to glial fibrillary acidic protein. In the peritumoral brain tissue, only neurons showed IR for Trk A and Trk B. On the contrary, in the tumour sections, the IR to both receptors was localized in the vast majority of glia and capillary endothelium. There was an obvious pattern of IR in these gliomas: high levels of IR were present in the low-grade (type I and II) astrocytoma; whereas in the advanced malignant forms (WHO grade IV giant cell glioblastoma and glio-blastoma multiforme) the IR was very weak. These findings suggest that Trk A and Trk B are involved in tumour pathogenesis, especially in the early stage, and may respond to signals that elicit glial proliferation, and thus contribute to progression towards malignancy.     

p75 neurotrophin receptor mediates neurotrophin activation of NF-kappa B and induction of iNOS expression in P19 neurons

P19 embryonic carcinoma cells can be differentiated into neurons that form synaptic connections and that produce a variety of neurotransmitters. Results of RT-PCR indicate that P19 neurons express several neurotrophin receptors (p75(NTR), trkB, and trkC, but not trkA) but they do not express any of the four neurotrophins. Consistent with the presence of trkB but not trkA, BDNF causes rapid phosphorylation of MAP kinases ERK1 and ERK2, but NGF does not. Neurotrophins induce translocation of NF-kappaB into the nucleus. All four neurotrophins induce activation of NF-kappaB in a biphasic manner. This effect is apparently mediated by p75(NTR), because an inhibitor of trk receptors, K252a, does not inhibit activation of NF-kappaB. Instead, K252a itself promotes activation of NF-kappaB and this effect is additive with the effect of neurotrophins. Inhibition of reactive oxygen intermediates with PDTC completely abolishes basal activity of NF-kappaB and strongly inhibits activation of NF-kappaB by neurotrophins, indicating an important role of reactive oxygen intermediates in the pathway by which neurotrophins activate NF-kappaB. NF-kappaB is known to promote expression of the iNOS gene. We found that all four neurotrophins increased iNOS mRNA levels, resulting in increased accumulation of iNOS protein. In contrast, none of the neurotrophins stimulated nNOS mRNA or protein synthesis. PDTC abolishes constitutive and neurotrophin-induced expression of iNOS mRNA and protein and abolishes constitutive expression of nNOS mRNA, suggesting that reactive oxygen intermediates promote expression of nNOS.