Mice Lacking the p75NGFR Receptor Exhibit Abnormal Responses to Light

A role for nerve growth factor (NGF) in the mammalian circadian system was assessed in mice using a line of gene targeted animals carrying a null mutation at the low affinity p75 NGFR receptor locus. Receptor-deficient mice exhibited positive phase angles of entrainment to 24 h light-dark cycles. In constant dark, circadian rhythms of behavior were normal but phase shifts induced by brief pulses of light were significantly decreased. These results support the hypothesis that NGF, through an action mediated at least in part by p75 NGFR receptors in the SCN, is involved in the regulation of circadian responses to light.     

p75(NGFR) and TrkA receptors collaborate to rapidly activate a p75(NGFR)-associated protein kinase.

The role of the low affinity nerve growth factor receptor (p75(NGFR)) in NGF-mediated signaling is not yet understood. Here we show by co-immunoprecipitation that NGF activates a protein kinase that is directly associated with p75(NGFR) in dorsal root ganglion (DRG) cells and PC12 cells in culture. Two proteins of 120 and 104 kDa constitute the majority of this activity. In PC12 cells, TrkA activation was necessary to elicit p75(NGFR)-associated kinase activity. Although NGF binding to p75(NGFR) was not necessary for kinase activation, it accelerated the activation of the kinase at low NGF concentrations. Deletion analysis showed that a 43 amino acid region in the cytoplasmic domain of p75(NGFR) was responsible for this effect. These findings show that p75(NGFR) accelerates TrkA-mediated signaling and, in addition, demonstrate that p75NGFR and TrkA collaborate to activate a previously undescribed p75(NGFR)-associated protein kinase.     

Targeted mutation of the gene encoding the low affinity NGF receptor p75 leads to deficits in the peripheral sensory nervous system.

We have generated mice carrying a mutation of the gene encoding the low affinity NGF receptor p75NGFR by targeted mutation in embryonic stem cells. Mice homozygous for the mutation were viable and fertile. Immunohistochemical analyses of the footpad skin of mutant mice revealed markedly decreased sensory innervation by calcitonin gene-related peptide- and substance P-immunoreactive fibers. The defective innervation was correlated with loss of heat sensitivity and associated with the development of ulcers in the distal extremities. Complicated by secondary bacterial infection, the ulcers progressed to toenail and hair loss. Crossing a human transgene encoding p75NGFR into the mutant animals rescued the absent heat sensitivity and the occurrence of skin ulcers and increased the density of neuropeptide-immunoreactive sensory innervation of footpad skin. The mutation in the gene encoding p75NGFR did not decrease the size of sympathetic ganglia or the density of sympathetic innervation of the iris or salivary gland. Our results suggest that p75NGFR has an important role in the development and function of sensory neurons.     

Retinoic acid regulates both expression of the nerve growth factor receptor and sensitivity to nerve growth factor.

In PC12 cells, retinoic acid (RA) stimulates the expression of p75NGFR, a component of the nerve growth factor (NGF) receptor, as indicated by a rapid increase in p75NGFR mRNA, an increase in the binding of 125I-labeled NGF to p75NGFR, and an increase in the binding of NGF to low affinity sites. RA-treated cells are more sensitive to NGF, but not to either fibroblast growth factor or phorbol 12-myristate 13-acetate, showing that RA has a specific effect on the responsiveness of PC12 cells to NGF. Exposure to RA leads neither to an increase in the expression of mRNA for trk, another component of the NGF receptor, nor to an increase in binding to high affinity receptors, suggesting that an increase in the expression of p75NGFR is sufficient to make cells more sensitive to NGF. This work suggests that, in addition to having direct effects on gene expression, RA can indirectly modulate differentiation of neurons by modifying their expression of cell surface receptors to peptide growth factors.     

Disruption of the low affinity receptor-binding site in NGF allows neuronal survival and differentiation by binding to the trk gene product.

Nerve growth factor (NGF), like many other growth factors and hormones, binds to two different receptor molecules on responsive cells. The product of the proto-oncogene trk, p140trk, is a tyrosine kinase receptor that has been identified as a signal-transducing receptor for NGF, while the role of the low affinity NGF receptor, p75NGFR, in signal transduction is less clear. The crystal structure of NGF has recently been determined, although structures involved in receptor binding and biological activity are unknown. Here we show that Lys-32, Lys-34, and Lys-95 form a positively charged interface involved in binding to p75NGFR. Simultaneous modification of Lys-32 with either of the two other lysines resulted in loss of binding to p75NGFR. Despite the lack of binding to p75NGFR, these mutants retained binding to p140trk and biological activity, demonstrating a functional dissociation between the two NGF receptors.     

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.     

Dorsal root ganglion neurons expressing trk are selectively sensitive to NGF deprivation in utero.

In utero immune deprivation of the neurotrophic molecule nerve growth factor (NGF) results in the death of most, but not all, mammalian dorsal root ganglion (DRG) neurons. The recent identification of trk, trkB, and trkC as the putative high affinity receptors for NGF, brain-derived neurotrophic factor, and neurotrophin-3, respectively, has allowed an examination of whether their expression by DRG neurons correlates with differential sensitivity to immune deprivation of NGF. In situ hybridization demonstrates that virtually all neurons expressing trk are lost during in utero NGF deprivation. Most, if not all, neurons expressing trkB and trkC survive this treatment. In contrast, the low affinity NGF receptor, p75NGFR, is expressed in both NGF deprivation-resistant and -sensitive neurons. These experiments show that DRG neurons expressing trk require NGF for survival. Furthermore, at least some of the DRG neurons that do not require NGF express the high affinity receptor for another neurotrophin. Finally, these experiments provide evidence that trk, and not p75NGFR, is the primary effector of NGF action in vivo.     

神经生长因子家族及其受体研究进展

过去几年在神经营养因子、受体和神经元细胞程序性死亡的研究领域中取得了几项引人注目的进展：（１）神经生长因子（ＮＧＦ）基因家族的其他一些成员包括脑源性神经营养因子（ＢＤＮＦ）、神经营养素－３（ＮＴ－３）、神经营养素－４（ＮＴ－４）、神经营养素－５（ＮＴ－５）的发现;（２）神经生长因子三维结构及功能和进化之关系的阐明;（３）定性了两种神经生长因子受体Ｐ７５＾ＮＧＦＲ和原癌基因ｐ１４０＾ｔｒｋＡ以及相关     

Multiple trkA proteins in PC12 cells bind NGF with a slow association rate.

Rat pheochromocytoma (PC12) cells express two distinct nerve growth factor receptors (NGFRs), p75NGFR and trkA (p140trk). In addition to these receptors, by using 125I-mNGF affinity labeling and BS3 chemical cross-linking of PC12 cell protein, we have identified two additional trkA protein bands with apparent molecular weights of 220,000 and 300,000. These bands contain trkA, but were not immunoprecipitated by p75NGFR-specific antisera, suggesting that they do not represent trkA/p75NGFR protein complexes. The 220-kDa trkA band apparently represents trkA with alternate post-translational modification. The appearance of the 300-kDa trkA band was dependent on cross-linker concentration and could be diminished in the presence of reducing agents, suggesting that it represents a trkA dimer. All trkA bands were phosphorylated on tyrosine residues when bound to mNGF, suggesting that they participate in NGF-induced signal transduction. NGF binding kinetics to all three trkA bands were indistinguishable, with slow dissociation rates, and a slow association rate that required approximately 1 h to reach equilibrium levels at 4 degrees C. All three trkA bands bound the related neurotrophin brain-derived neurotrophic factor and neurotrophin-3 with a profile characteristic of trkA.     

Expression of the NGF receptor gene in sensory neurons and their cutaneous targets prior to and during innervation

We have studied the expression of NGF receptor (NGFR) mRNA in the mouse trigeminal system at closely staged intervals throughout development. The level of NGFR mRNA per neuron is at a constant low level before the earliest axons reach the target field and increases 5-fold to plateau shortly after the arrival of the last axons. NGFR mRNA expression in developing target skin is restricted to mesenchyme, precedes the arrival of the earliest axons, and increases throughout the phase of target field innervation. These findings suggest that NGFR expression on sensory neurons occurs at a low level prior to target field innervation and is up-regulated with this event, and they raise the possibility that NGFRs on mesenchymal cells restrict the distribution of NGF in the target field.     

Nerve growth factor and tissue repair remodeling: trkA(NGFR) and p75(NTR), two receptors one fate

This review deals with the role of nerve growth factor (NGF) in healing process as a result of injury. The role of both trkA(NGFR) and p75(NTR) specific NGF receptors and their contribution in the complex network of tissue repair process, is discussed and highlighted in view of recent findings. In fact, NGF represents a significant advance in the treatment of etiologically different ulcers (corneal ulcers, pressure ulcers, post-viral infections, chemical burns) and might shorten the recovery process. For these diseases, no specific treatment is actually available. It is reasonable that apart from NGF and/or neurotrophins a different time-course of trkA(NGRF)/p75(NTR) expression, might regulate the final process. In summary, these novel findings on the potential pro-healing capacity of NGF might open new possibilities for this growth factor in modulating the healing processes in several pathological conditions.     

Multiple defects of the nerve growth factor receptor in human neuroblastomas

Neuroblastoma is a tumor of postganglionic sympathetic origin, and nerve growth factor (NGF) is normally required for the survival and differentiation of sympathetic neuroblasts. Since the biological activity of NGF is mediated by the NGF receptor (NGFR), we hypothesized that defects in the NGF/NGFR pathway may play a role in maintenance of the undifferentiated state of neuroblastomas. To test this hypothesis, we examined the structure of the NGFR at the DNA, RNA, and protein levels in a panel of 10 neuroblastoma cell lines. In addition, we examined the function of the NGFR in these lines by analysis of NGF binding kinetics, as well as by the ability of NGF to induce c-fos expression and neurite outgrowth. Southern blot analysis showed that all 10 cell lines possess apparently normal NGFR genes. Northern blot and ligand binding/immunoprecipitation assays revealed four receptor-positive cell lines (NGP, NLF, SK-N-SH, and LA-N-6), with NGFR mRNA and protein of expected sizes (3.8 kilobases and Mr approximately 75,000, respectively). NGF binding assays and Scatchard analyses were performed on the four NGFR-positive lines. The NGP line possesses only low-affinity receptor (Kd approximately 3.5 x 10(-9)), whereas the other three lines express both low- and high-affinity forms (Kd approximately 10(-9) and Kd approximately 10(-11), respectively). However, none of the 10 lines exhibited a response to NGF treatment as assayed by c-fos mRNA induction and neurite extension.(ABSTRACT TRUNCATED AT 250 WORDS)     

An autocrine function of nerve growth factor for cell cycle regulation of vascular endothelial cells

Nerve growth factor (NGF) regulates maintenance, survival, and function of not only neuronal cells but also various kinds of non-neuronal cells. Here we clearly demonstrated that mouse aortic endothelial cells (AEC) produced bioactive NGF, and the production was enhanced by a proinflammatory cytokine, interleukin (IL)-1beta. AEC expressed both high affinity (TrkA) and low affinity (p75(NGFR)) receptors for NGF. Exogenously added NGF induced rapid phosphorylation of TrkA tyrosine kinase. Addition of anti-NGF neutralizing antibody resulted in an increase in the proportion of AEC in S and G(2)/M phases and in a hypodiploid range. Since the vascular endothelium plays a pivotal role in inflammatory conditions, these results strongly suggest that NGF, whose production is enhanced at the affected site, may contribute to maintenance, survival, and function of vascular endothelial cells by autocrine and/or paracrine mechanisms.     

Removal of C6 Astrocytoma Cell Surface Molecules with Phosphatidylinositol Phospholipase C: Effect on Regulation of Neurol Cell Adhesion Molecule Isoforms

In earlier studies, a 75,000-dalton glycoprotein (gp75) has been identified as a component of both low- and high-affinity nerve growth factor (NGF) receptors (NGFRs). Using an amphoteric expression vector, we have introduced the cDNA encoding the human gp75 into two neuroblastoma cell lines. SHEP is a human neuroblastoma cell line that lacks most neuronal characteristics and does not express NGFRs. The transformant line SHEP/NGFR expressed a single affinity class of NGF binding sites, did not display NGF-induced up-regulation of fos oncogene expression, and did not efficiently internalize NGF. LAN5 is a neuroblastoma cell line with neuronal characteristics, including expression of neurofilament and display of short neurites. This cell line expresses a small number of high-affinity NGFRs but no detectable low-affinity sites. The transformant line LAN5/NGFR expressed both high- and low-affinity NGFRs, displayed NGF-induced up-regulation of fos oncogene, and efficiently internalized NGF. The number of high-affinity NGF binding sites was nearly the same for LAN5 and LAN5/NGFR, a finding suggesting that there is a limiting number of some separately coded factor or subunit that is required for high-affinity NGFRs. Because NGF induction of fos oncogene expression correlated with expression of high-affinity NGFRs, the putative second factor may also limit NGF responsiveness.     

Effects of NGF and glucocorticoid on NGF receptor immunolabeling of cultured rhesus adrenal chromaffin cells

Nerve growth factor (NGF) promotes the outgrowth of neurites from cultured adrenal chromaffin cells from adult rhesus monkeys, but little is known about the distribution, at the cellular level, of the NGF receptors (NGFR) responsible for this response. We examined changes in immunostaining for NGFR in chromaffin cells cultured for 4 weeks in the presence or absence of NGF, with or without dexamethasone (DEX), which inhibits neuritic outgrowth from these cells. Purified cultures of adrenal chromaffin cells from adult rhesus monkeys were grown for up to 9 weeks in NGF, DEX, NGF plus DEX, or control medium. Cells were immunolabeled with three different monoclonal antibodies directed against different epitopes of the human NGFR. Although the distribution of immunolabeling was not uniform from cell to cell, the overall intensity of NGFR immunolabeling varied dramatically between different growth conditions. Of greatest interest, DEX-treated cells stained the most intensely at all time points, while the intensity of immunolabeling was much fainter in NGF-treated cells and decreased with time in culture. In contrast to the intensity of labeling, the proportion of chromaffin cells with immunoreactivity increased with time in all treatment groups. Thus, GCs do not appear to antagonize the effects of NGF merely by decreasing the total number of immunoreactive NGFR on the surface of these cells.     

Disruption of cysteine-rich repeats of the p75 nerve growth factor receptor leads to loss of ligand binding.

Nerve growth factor (NGF) binds to a low affinity cell surface receptor (p75NGFR) which contains four extracellular repeats, rich in cysteine residues and negatively charged. We have made mutations in the receptor cDNA by inserting linkers in specific domains of the receptor. Nearly all the mutations caused a change in the predicted charge, and resulted in either an insertion or deletion in the primary sequence. Stably transfected fibroblasts were assayed for NGF binding by affinity cross-linking with 125I-NGF. Appropriate expression of the mutated receptors was monitored by rosetting with monoclonal antibodies and by metabolic labeling followed by immunoprecipitation. Although the mutant receptors were recognized by monoclonal antibodies, insertions and deletions in the third and fourth cysteine-rich regions of the receptor had a detrimental effect upon NGF binding. Insertions made outside the cysteine-rich region or in the cytoplasmic domain did not inhibit the ability of 125I-NGF to bind to the receptor, as assessed by affinity cross-linking. A chimeric human-rat NGF receptor transfected into fibroblasts indicates that NGF binding and monoclonal antibody recognition sites are separated but contained within the four cysteine repeats.     

Interactions between light and melatonin on the circadian clock of mice.

Melatonin and light synchronize the biological clock and are used to treat sleep/wake disturbances in humans. However, the two treatments affect circadian rhythms differently when they are combined than when they are administered individually. To elucidate the nature of the interaction between melatonin and light, the present study assessed the effect of melatonin on circadian timing and immediate-early gene expression in the suprachiasmatic nucleus (SCN) when administered in the presence of light. Male C3H/HeN mice, housed in constant dark in cages equipped with running wheels, were treated with either melatonin (90 microg, s.c.) or vehicle (3% ethanol-saline) 5 min prior to exposure to light (15 min, 300 lux) at various times in the circadian cycle. Combined treatment resulted in lower magnitude phase delays of circadian activity rhythms than those obtained with light alone during the early subjective night and advances in phase when melatonin and light were administered during the subjective day (p < .001). The reduction in phase delays with combined treatment at Circadian Time (CT) 14 was significant when light exposure measured 300 lux but not at lower light levels (p < .05). When light preceded melatonin administration, the inhibition of phase delays attained significance only when the light exposure reached 1000 lux (p < .05). Neither basal nor light-induced expression of c-fos mRNA in the SCN was modified by melatonin administration at CT 14 or CT 22. Together, these results suggest that combined administration of melatonin and light affect circadian timing in a manner not predicted by summing the two treatments given individually. Furthermore, the interaction is not likely to be due to inhibition of photic input to the clock by melatonin but might arise from a photically induced enhancement of melatonin's actions on circadian timing.