Nerve growth factor potentiates actomyosin adenosinetriphosphatase

Tubulin immunoreactive neuronal intranuclear inclusions in the human brain

Intranuclear filamentous and crystalline inclusion bodies have been described in the nuclei of a variety of cells in both normal and pathological states. The functional significance of these structures remains to be elucidated. Moreover, although the proteinaceous nature of these inclusions has been inferred in some histochemical studies, the identity of their constituent proteins remains to be determined. In the present study, immunohistochemistry was used to investigate the presence of intranuclear inclusions in neurones of the human brain which are intensely immunoreactive for the neuronal cytoskeletal protein class III beta tubulin. The ability to label these structures immunohistochemically was exploited to investigate the topographic pattern of distribution of these inclusions in the human brain. Intranuclear inclusions were rod-shaped, polygonal, or irregular in shape. They were present in neurones and ependymal cells. Intranuclear inclusion-bearing neurones were distributed in an anatomically heterogeneous pattern in the brain. Areas exhibiting relatively high densities of inclusions included the substantia inominata and anterior olfactory nucleus, dentate gyrus, substantia nigra, inferior olivary nucleus, and dentate nucleus of the cerebellum. In addition, intranuclear inclusions were prevalent in neurones in layers II, V, and VI of the cerebral cortex. They were particularly prevalent in the mesial basal temporal neocortex. The relationship of these structures to the intranuclear rods and sheets of the classical microscopists is uncertain. The demonstration that they are composed, at least in part, of tubulin, a major cytoskeletal protein, provides important clues regarding the mechanisms underlying their formation and provides a springboard for developing hypotheses regarding their functional significance. Furthermore, the ability to demonstrate these inclusions immunohistochemically provides an avenue for further studies directed at elucidating the potential involvement of these inclusions in various pathological settings.

Is signal transduction modulated by an interaction between heterotrimeric G-proteins and tubulin?

Although it is generally accepted that tubulin plays an important role in G-protein-mediated signal transduction in a variety of systems, the mechanism of this phenomenon is not completely understood. G-protein-tubulin interaction at the cell membrane and the cytosol, and the influence of such an interaction on cellular signaling are discussed in this review article. Because the diameter of a microtubule is 25 nm and the plasma membrane is 9-11 nm thick, it is not possible for membrane-associated tubulin to assemble into a complete microtubule in the membrane environment. However, tubulin heterodimers may be able to function in the membrane environment as individual heterodimers or as polymers arranged into short protofilaments. At the cell membrane, membrane-associated tubulin may influence hormone-receptor interaction, receptor-G-protein coupling, and G-protein-effector coupling. Structural proteins, such as tubulin, can participate in cellular signaling by communicating through physical forces. By virtue of its interaction with the submembranous network of cytoskeletal proteins, tubulin, when perturbed in one locus, can transmit large changes in conformations to other points. Thus, GTP binding to membrane-associated tubulin might lead to a conformational change in either receptors or G proteins. This may, in turn, influence the binding of an agonist to its receptor. On the other hand, in the cell cytosol, subsequent to agonist-induced translocation of G-proteins from the membrane compartment to the cytosol, G-proteins may affect microtubule formation. In GH3 and AtT-20 cells (stably expressing TRH receptor), transiently transfected with Gq alpha cDNA, soluble tubulin levels decreased in Gq alpha-transfected GH3 and AtT-20 cells, by 33% and 52%, respectively. These results suggest that G-proteins may have a direct effect on the microtubule function in vivo. Because tubulin and G-protein families are ubiquitous and highly conserved, an interaction between these two protein families may occur in vivo, and this, in turn, can have an impact on signal transduction. However, the physiological significance of this interaction remains to be demonstrated.

Drugs that influence tubulin polymerization modulate thyrotropin-releasing hormone receptor number in AtT-20 cells

In order to examine the role of cytoskeleton in modulating the cell surface receptors, AtT-20 cells (stably expressing thyrotropin-releasing hormone receptors) were incubated with drugs that are known to modify the tubulin-microtubule system. The binding of [3H]methyl thyrotropin-releasing hormone ([3H]mTRH) to intact cells increased as a function of time, and was linear from 1.25 x 10(6) to 6.25 x 10(6) cells/ml. Cells incubated with colchicine, vinblastine, and taxol for 16 hr were harvested and the cell concentration was determined using a haemocytometer. Because the drugs inhibited the cell proliferation at 100 nM, it was decided to examine the effect of 100 nM of each of the three drugs on the ability of [3H]mTRH to bind cell surface receptors. Cells were incubated with the drugs for 16 hr at 37 degrees. After the incubation, cells (5 x 10(6) cells/ml) from each group were assayed for [3H]mTRH binding. Colchicine, vinblastine, and taxol stimulated [3H]mTRH binding by up to 27, 27, and 21%, respectively, without altering the Ka of the ligand to the receptor. These results suggest that perturbation of cytosolic microtubules leads to a reorganization of the spatial location of hormone receptors.

Expression of the beta-nerve growth factor gene in male sex organs of the mouse, rat, and guinea pig

Steady-state nerve growth factor (NGF) mRNA levels were estimated in male sex organs of the mouse, rat, and guinea pig by RNA blot hybridization analysis. The abundance of NGF mRNAs was in the order vas deferens greater than epididymis greater than or equal to seminal vesicles much greater than testis. NGF mRNA levels in these organs were compared with those estimated for other rat peripheral tissues and were found to correlate with the density of their sympathetic innervation, with the exception of guinea pig prostate. Castration had no significant effect on NGF mRNA levels in the guinea pig prostate, suggesting that NGF synthesis in this tissue is not under direct androgen control. NGF-like and proNGF-like immunoreactivities were localized by immunohistochemical techniques in the secretory cells of the glandular epithelium of the guinea pig prostate and in germ cells in the seminiferous tubules of the mouse testis.

Synapsin I bundles F-actin in a phosphorylation-dependent manner

Synapsin I is a neuron-specific phosphoprotein localized to the cytoplasmic surface of synaptic vesicles. This phosphoprotein is a major substrate for cyclic AMP-dependent and calcium/calmodulin-dependent protein kinases. Its state of phosphorylation can be altered both in vivo and in vitro by a variety of physiological and pharmacological manipulations known to affect synaptic function. Recent direct evidence suggests that it may be involved in the regulation of neurotransmitter release from the nerve terminal. In the nerve terminal, synaptic vesicles are embedded in a cytoskeletal network, consisting in part of actin. We report here the ability of the dephospho-form of synapsin I to bundle F-actin. This bundling activity is reduced when synapsin I is phosphorylated by cAMP-dependent protein kinase and virtually abolished when it is phosphorylated by calcium/calmodulin-dependent protein kinase II or by both kinases. These results, demonstrating an interaction of synapsin I with actin in vitro, support the possibility that synapsin I is involved in clustering of synaptic vesicles at the presynaptic terminal and that the phosphorylation of synapsin I may be involved in regulating the translocation of synaptic vesicles to their sites of release.

Fragmin induces tension reduction of actomyosin threads in the presence of micromolar levels of Ca2+

Fragmin was able to reduce the isometric tension of Physarum actomyosin threads to 15-30% of the control tension at the Ca2+ concentrations greater than 10(-6) M. However, fragmin had no effect on the tension of threads when the Ca2+ concentration was lowered below 10(-7) M. The tension once reduced by fragmin could not be recovered by the removal of Ca2+. The remaining tension was shown to be still active from the experiment with quick release or stretch of the thread. This tension reduction is parallel to the decrease in viscosity of F-actin solution by fragmin. Electron microscopy showed that F-actin filaments became shorter in the thread after the tension was reduced by fragmin. Therefore, the severing of F-actin by fragmin in micromolar concentration of calcium resulted in the relaxation of tension by actomyosin threads.

Microtubules and microfilaments in fixed and permeabilized cells are selectively decorated by nerve growth factor

A specific antibody against nerve growth factor (NGF) and indirect immunofluorescence microscopy have been used to follow the in vitro binding of NGF to cells made permeable to large molecules. All cells tested, both target (sensory neurons and PCI2 cells) and nontarget (3T3, BKH 2I, C6 glioma cells), revealed a decoration of cytoskeletal structures which on the basis of their form, reactivity with antibodies, and sensitivity to specific drugs may be identified as microtubules (MTs) and microfilaments (MFs). The decoration of either structure depends on the fixation and permeabilization conditions: MFs, in the form of stress fibers, are stained by NGF when the plasma membrane is permeabilized with methanol/acetone; MTs become intensely stained when the plasma membrane is solubilized with a nonionic detergent in the presence of a MT-stabilizing medium. The two procedures do not affect the staining of these structures with specific antibodies. Binding of 125I-labeled NGF to PCI2 cells was not competitively inhibited by a 100-fold excess of several positively charged proteins but it was markedly decreased in the presence of DNase I. 125I-Labeled NGF interacted with MTs and F-actin (fixed with paraformaldehyde) in a range of concentrations similar to that used for their cellular localization with NGF-anti-NGF. Our studies show that the specificity and affinity of NGF binding to MTs and MFs is in the range of that of antibodies against tubulin and actin. The possible relevance of these findings to the mechanism of action of NGF in target cells is discussed.

Interaction of [125I] beta nerve growth factor with acidic proteins

We have demonstrated that the beta nerve growth factor will interact with various acidic proteins apparently nonspecifically. When 125I-labeled beta nerve growth factor at a concentration of 3.8 X 10(-10) M is incubated with an acidic protein at 2 mg/ml (4.5 X 10(-6)-4.4 X 10(-5) M), a complex is formed. This complex changes the isoelectric point of the 125I-labeled beta nerve growth factor sufficiently so that the 125I-labeled beta nerve growth factor migrates anomalously in polyacrylamide gel electrophoresis. The interaction between beta nerve growth factor and bovine serum albumin, which appears to be complex, may be the cause of the previously reported activation of the beta nerve growth factor when bovine serum albumin is present in a typical bioassay.

Mobility, clustering, and transport of nerve growth factor in embryonal sensory cells and in a sympathetic neuronal cell line

We have prepared a fluorescent conjugate of nerve growth factor (NGF) containing 8--10 rhodamine molecules attached to free carboxyl groups of the protein. This analogue retained full binding capacity toward NGF receptors, full antigenic properties, and the potency to stimulate the differentiation of embryonal chicken sensory ganglia cells in vitro. We have used this analogue to study the mobility and distribution of NGF receptors on embryonal chicken sensory cells from dorsal root ganglia and on a pheochromocytoma cell line (PC-12) that responds to NGF by differentiating along a neuronal pathway. The rhodamine conjugate of nerve growth factor (R-NGF) binds initially to diffusely distributed mobile receptors (D approximately 8 X 10(-10) cm2/sec) on immature sensory and PC-12 cells. At 37 degrees C, the NGF receptor complexes cluster and form immobile visible patches. These patches undergo endocytosis in a process that consumes metabolic energy. Methylamine blocks the formation of visible patches of NGF and the receptors remain dispersed and mobile at 37 degrees C. On differentiated chicken sensory cells, R-NGF binds to diffusely distributed mobile receptors and to aggregated immobile binding sites. These clusters are localized at the tip of the axon, along the axon, and in the main body. The NGF molecules that are internalized at the tip of the axon are transported retrogradely from the peripherey to the cell body.

Intracellular distribution of nerve growth factor in rat pheochromocytoma PC12 cells: evidence for a perinuclear and intranuclear location

The distribution of nerve growth factor (NGF) in rat pheochromocytoma cells (clone PC12) has been studied with two different techniques: immunofluorescence and autoradiography. It was found that NGF is progressively internalized in the cytoplasmic compartment and eventually accumulates in the form of discrete dots around the nucleus. A fraction of the internalized NGF appears within the nucleoplasm, often contiguous with the nucleolus. It is suggested that cytoplasmic and perinuclear NGF may be be in contact with a pool of tubulin or actin-like proteins in their soluble or organized form and play a key role in the process of arrest of division and neurite growth.

Cell density modulates receptor-mediated internalization of nerve growth factor in pheochromocytoma cells

Binding and fate of the nerve growth factor (NGF) in pheochromocytoma cells (clone PC12) have been measured with the use of iodine-labeled ligand and with 125I-NGF antibodies. With such double approach it is possible to distinguish between surface bound and total NGF bound to PC12 cells. It is found that NGF-receptor complexes undergo down-regulation. This process is noticeable at low but not at high cell densities, and only in PC12 cells never exposed to NGF. Previous incubation with growth factor leads to the disappearance of down-regulation of NGF-receptor complexes. Assuming that this process is an indirect measure of NGF-receptor internalization, it is concluded that it is modulated by the cell density or by previous exposure to the factor. These findings are postulated to be relevant to the mechanism of action of NGF and to its multiple effects on target cells.

Evidence for RNA synthesis-dependent and -independent pathways in stimulation of neurite outgrowth by nerve growth factor

Studies on the mechanism of action of nerve growth factor (NGF) were carried out with PC12 rat pheochromocytoma cells. PC12 cells are uniquely useful for such studies because they respond to, but (unlike normal neurons) do not require, NGF and may undergo either generation or regeneration of neurites in response to NGF. Regeneration is defined here as NGF-dependent regrowth of neurites within 24 hr after subculture of NGF-treated PC12 cells. As in cultures of normal NGF-responsive neurons, neurite regeneration by PC12 cells occurs even in the presence of high concentrations of RNA synthesis inhibitors. Generation of neurites is defined as the de novo initiation of outgrowth when PC12 cells are exposed to NGF for the first time. In contrast to regeneration, neurite generation takes place with a lag of at least 24 hr and is blocked by low concentrations of RNA synthesis inhibitors. Such findings suggest that there are both RNA synthesis-dependent and -independent pathways in the mechanism whereby NGF stimulates neurite outgrowth. In addition, NGF-treated PC12 cells undergo a time-dependent loss of the capacity for neurite regeneration after pretreatment with RNA synthesis inhibitors or withdrawal of NGF. Such findings suggest that (i) initiation of neurite outgrowth requires NGF-stimulated, RNA synthesis-dependent accumulation of intracellular material(s), (ii) once such accumulation occurs, RNA synthesis-independent regeneration can occur (but only in the presence of NGF), and (iii) the turnover of such material(s) in the absence of their replacement leads to loss of the capacity for regeneration. A tentative sequence is presented for the events whereby NGF may stimulate neurite outgrowth.