S-100 proteins

S-100 protein localization in human adult dental pulp

The pulp of third molar teeth was examined by immunofluorescence and immunoperoxidase using a specific antibody to detect S-100 protein-labelled cells. There was a strong positive reaction in macrophages and in Schwann cells ensheathing axons. The other cells within the pulp were negative.

S-100 protein stimulates cellular proliferation

S-100 protein (S-100p) is a small, acidic, calcium-binding protein that is present (predominantly) in the cytoplasm of many types of cells including those of neuroectodermal origin, such as glial cells, schwann cells and melanocytes. In human melanoma cells S-100p is abundant relative to the small quantities expressed by normal melanocytes. We investigated the possibility that this protein may be a growth factor. Purified S-100p from bovine brain or human melanoma cells was added exogenously to human melanoma cells and peripheral blood lymphocytes (PBL) and their growth in the presence of different concentrations of S-100p was determined using a [3H]dT-uptake proliferation assay. The growth of melanoma cells was stimulated by S-100p at concentrations of 1.95-31.25 micrograms/ml. Slight inhibition of cell proliferation occurred at high concentrations (125 micrograms/ml). Maximum stimulation of PBL was at 31.25 micrograms/ml. PBL were not inhibited even at high concentrations of S-100p (125 micrograms/ml). PBL stimulation by S-100p did not require the presence of monocytes/macrophages. Though stimulation by S-100p is not restricted to a specific cell type, when released by melanoma cells it may function as an "autocrine" tumor growth factor. Other cells, such as PBL, coming in contact with S-100p are also stimulated to proliferate.

Glia:neuron index: review and hypothesis to account for different values in various mammals

The present paper proposes a hypothesis to account for different values of the glia:neuron index in comparable central nervous system tissues of various mammals. This hypothesis assumes that K+ ions released by active neurons are a mitogenic signal for glial cells. The thicker the tissue (for example, the brain wall), the more difficult is efficient K+ clearance, and more perinatal glial cell proliferation should occur. Thus, this hypothesis accounts for higher glia:neuron indices in mammals with thicker brain walls.

Analysis of the calcium-modulated proteins, S100 and calmodulin, and their target proteins during C6 glioma cell differentiation

We have analyzed the levels, subcellular distribution, and target proteins of two calcium-modulated proteins, S100 and calmodulin, in differentiated and undifferentiated rat C6 glioma cells. Undifferentiated and differentiated C6 cells express primarily the S100 beta polypeptide, and the S100 beta levels are four-fold higher in differentiated compared to undifferentiated cells. Double fluorescent labeling studies of undifferentiated cells demonstrated that S100 beta staining localized to a small region of the perinuclear cytoplasm and colocalized with the microtubule organizing center and Golgi apparatus. Analysis of differentiated C6 cells demonstrated that S100 beta distribution and S100 beta-binding protein profile changed significantly upon differentiation. In addition, the brain-specific isozyme of one S100-binding protein, fructose-1,6-bisphosphate aldolase C, can be detected in differentiated but not undifferentiated C6 cells. While changes in the subcellular distribution of calmodulin were not observed during differentiation, calmodulin levels and calmodulin-binding protein profiles did change. Altogether these data suggest that S100 beta and calmodulin regulate different processes in glial cells and that the regulation of the expression, subcellular distribution, and target proteins of S100 beta and calmodulin during differentiation is a complex process which involves multiple mechanisms.

S-100b protein regulates the activity of skeletal muscle adenylate cyclase in vitro

We have investigated the effect of the b isoform of S-100 proteins on adenylate cyclase activity of rat skeletal muscle. S-100b inhibits the adenylate cyclase activity in the presence of Mg2+ (5.0-50 mM), while it activates the same enzyme in the presence of Ca2+ (0.1-1.0 mM) dose-dependently in both cases. S-100b counteracts the stimulatory effect of NaF on adenylate cyclase in the presence of Mg2+ and the inhibitory effect of RMI 12330 A in the presence of Ca2+.

Expression of 48-kilodalton intermediate filament-associated protein in differentiating and in mature astrocytes in various regions of the central nervous system

In this paper we present evidence that the 48-kD intermediate filament-associated protein (IFAP) is expressed relatively late in maturation of astrocytes, after they have acquired the glial fibrillary acidic protein (GFAP). In the astrocytes of white matter in the cerebellum the GFAP is detected at P3, whereas the 48-kD IFAP is detected only at P11. In the periventricular region and the hippocampus the 48-kD IFAP was detected at P6, long after the appearance of GFAP. In adult mice the 48-kD IFAP was observed in GFAP-positive astrocytes in the white matter of cerebellum, spinal cord, brainstem, and corpus callosum as well as in GFAP-positive cells in the grey matter of cerebral cortex and spinal cord. The 48-kD IFAP was not, however, detected in radial glia and their derivatives, in Bergmann glia or in Müller glia. Thus, not all the GFAP-positive astroglia express the 48-kD IFAP. Similarly, 48-kD IFAP was not detected in cells which were GFAP-negative.

Approaches to study the role of S100 proteins in calcium-dependent cellular responses

Calcium is necessary for the optimal growth and cellular functions of most living organisms. For example, Ca is involved in the processes of muscle contraction, stimulus-secretion coupling, bone formation, blood clotting, cell proliferation and motility, and fertilization. Many regulatory actions of Ca are mediated through Ca-binding proteins. Calcium-modulated proteins are a subclass of Ca-binding proteins that are thought to be the major signal transducers of Ca acting as a cellular second messenger. Most Ca-modulated proteins are not enzymes but are effector proteins capable of transducing a Ca signal into a biological response by their ability to bind Ca reversibly and modulate the activity of other proteins in a Ca-dependent manner. This review focuses on a set of Ca-modulated proteins, the S100 proteins, and their possible roles in mediating Ca-dependent cellular events.

Immunohistochemical demonstration of S-100 protein in the brain neurosecretory cells of invertebrates (insects and earthworms)

This immunohistochemical study demonstrated the presence of S-100 protein (-like substance) in the nervous systems of some invertebrate animals. The immunoreactivity of S-100 protein was detected in some neurosecretory cells, but not in glial cells in the brains (cerebral ganglia) of silkworms, cockroaches and earthworms. The immunoreactive nerve fibers extended to the neurohemal organs. These results suggested the possibility that S-100 protein (-like substance) may act as a neurohormone or carrier protein in invertebrate animals.

Interaction of S-100b protein with cardiolipin vesicles as monitored by electron spin resonance, pyrene fluorescence and circular dichroism

The interaction of S-100b protein with cardiolipin (CL) vesicles has been studied by electron spin resonance, pyrene fluorescence, and circular dichroism. Electron spin resonance and pyrene fluorescence data indicate that S-100b binds to the polar surface of vesicles Ca2+-independently. In the presence of Ca2+, S-100b potentiates the Ca2+-induced clustering of the polar headgroups of CL molecules and causes a further reduction in the Ca2+-dependent decrease in the lateral mobility of the pyrene inserted into the lipid bilayer, which points to an effect of the protein on the hydrophobic core of the lipid bilayer through a larger perturbation of its polar surface. Circular dichroism analyses indicate that CL vesicles cause a decrease in the alpha-helical content of S-100b, analogous to that produced by Ca2+ and that the effects of CL vesicles and of Ca2+ on the secondary structure of the protein are supra-additive. By this technique, we found that the affinity of Ca2+ for S-100b increases substantially in the presence of CL vesicles, even in the presence of physiologic concentrations of KCl, suggesting that once S-100b had interacted with CL vesicles it assumes a new conformation in which its Ca2+-binding properties are greatly enhanced. These results are discussed in relation to binding of S-100b proteins to natural membranes, and to a possible involvement of S-100b in the regulation of membrane structural organization.

Large-scale, one-step purification of oxidized and reduced forms of bovine brain S100b protein by HPLC

A rapid and simple method, using a reverse-phase column in a HPLC system, has been developed to purify high yields of both oxidized and reduced S100b proteins from a bovine brain S100 protein mixture. The final proteins were characterized by amino acid analysis, sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and absorbance and fluorescence spectroscopy. Both S100b subtypes appeared highly purified and differed only by their oxidation state: all four cysteinyl sulfhydryl groups were free in reduced S100b protein whereas two of them gave disulfide bridges in oxidized S100b protein. The stability of the oxidation state of the two isolated subtypes suggests that the two forms were not in rapid equilibrium and probably coexisted in vivo.

Nerve growth factor induces the genes for two proteins related to a family of calcium-binding proteins in PC12 cells

Differential hybridization of a cDNA library from rat pheochromocytoma PC12 cells with cDNA probes from naive PC12 cells and from PC12 cells exposed to nerve growth factor for 7 days identified cDNA sequences of two genes induced by NGF. The mRNA species detected by these cDNA sequences, designated 42A and 42C, reached maximal levels after 24 hr of treatment with NGF and were still significantly higher than control levels after 7 days. Epidermal growth factor transiently induced both mRNAs but at much lower levels. The mRNAs code for 95- (42C) and 101- (42A) amino acid residue peptides whose sequences are homologous to those of a family of calcium-binding proteins including the S-100 protein. The conservation of primary and secondary structure between 42A, 42C, and the other proteins suggests a possible role for them in the regulation of cell growth and differentiation.

Ultracytochemical localization of adenylate cyclase and guanylate cyclase in crushed peripheral nerves

Cellular and subcellular distribution of adenylate cyclase (AC) and guanylate cyclase (GC) activities in crushed peripheral nerves during regeneration were studied at the electron microscope level. In unlesioned nerves, no AC reaction product could be evidenced, whereas GC was detectable on the plasma membranes of Schwann cells, myelinated and nonmyelinated fibers, and within nonmyelinated axons. At 24 hours after the crush, AC reaction product was found within axonal segments proximal to the zone of the crush in association with mitochondria. At this stage, macrophage-like cells, which probably are transformed Schwann cells, polymorphonuclear leucocytes, and endothelial cells displaying an intense AC reaction product could be detected. On the other hand, at 24 hours after the crush, GC was no longer detectable, except on occasional unlesioned nerve fibers. At 48 hours after the lesion, AC reaction product was no longer detectable within axons, and all AC positivity was associated with plasma membranes of non-neuronal cells, including transformed Schwann cells, occasional macrophages, polymorphonuclear leucocytes, fibroblasts, and elongated cells. As to GC, images similar to those obtained at 24 hours were observed until 48 hours after the crush. From the 7th to the 28th postlesion day, AC activity was localized exclusively to the plasma membranes of fibroblasts and elongated cells. Transformed Schwann cells were no longer detectable, whereas normal Schwann cells and regenerating axons could be seen, and these showed no AC reaction product in analogy to the absence of AC reaction product of unlesioned nerves. During the same period, GC again was detectable on regenerating fibers with the same subcellular localization as that of unlesioned nerves. The present results strongly suggest that starting from the second postcrush day, cells invading the lesioned zone and transformed Schwann cells, all taking part in the formation of the new perineurial tissue, display a high AC activity, which should be taken into account when measuring cyclic adenosine monophosphate (cAMP) levels under these conditions. Also, our data suggest that GC is involved primarily in regeneration processes that occur in crushed peripheral nerves. Thus, the pattern of AC distribution in peripheral unlesioned and lesioned nerves appears to be exactly the opposite of the GC localization examined under similar experimental conditions insofar as nervous fibers are concerned.

Secretion of S-100 from rat C6 glioma cells

Conditioned media from rat C6 glioma cells contain significant levels of S-100 immunoreactivity as determined by radioimmunoassay. The levels of extracellular S-100 detected could not be accounted for by the release of intracellular S-100 into the media from lysed cells. The extracellular form of S-100 exhibits fractionation properties and immunological characteristics that are different from those of the intracellular form of S-100 in C6 cells. While the intracellular S-100 levels increase as a function of days in culture, the extracellular S-100 levels are high until the cells reach confluency and are lower in postconfluent cultures. Altogether, our data suggest that C6 glioma cells secrete S-100, and that the quantitative levels of the intracellular and secreted forms of S-100 are differentially regulated.

Effect of anti-S-100 serum on 36Cl- ion permeability across the Deiters' neuron plasma membrane

1. A microtechnique allowing the study of single plasma membranes from the gamma-aminobutyric acid (GABA)-acceptive Deiters' neuron has been utilized in order to assess the effect of both S-100 protein and its antiserum on 36Cl- permeability through such membranes. 2. The results show that both S-100 (in the Ca2+ form) incorporation onto the external side of the membranes and their preincubation with anti-S-100 serum stimulate 36Cl- permeability. 3. These effects are not additive with that of GABA, indicating that both S-100 and anti-S-100 act via the GABAA receptor complexes on Deiters' membranes. 4. When the membranes were incubated first with S-100/Ca2+ and then with anti-S-100, the second treatment resulted in the disappearance of the S-100 effect. However, the anti-S-100 effect was fully displayed.

Purification and properties of a novel Ca2+-binding protein (10.5 kDa) from Ehrlich-ascites-tumour cells

A novel Ca2+-binding protein (CaBP) was identified in Ehrlich-ascites-tumour cells and purified to homogeneity. The molecular mass of this protein is about 10.5 kDa as estimated by polyacrylamide-gel electrophoresis in the presence of SDS. CaBP has two Ca2+-binding sites that bind Ca2+ with a dissociation constant of about 3 x 10(-6)M. Ca2+ binding to CaBP decreases its electrophoretic mobility in urea/polyacrylamide gels, changes its u.v. spectrum, increases the intrinsic tyrosine fluorescence intensity and strengthens hydrophobic interaction with the phenyl-Sepharose matrix.

Characteristics of the effect of S-100 proteins on the assembly-disassembly of brain microtubule proteins at alkaline pH in vitro

The ability of S-100 proteins to inhibit the assembly of brain microtubule proteins (MTPs) in the presence of microM levels of Ca2+ increases as a function of pH. This seems to be due to an increasingly larger inhibitory effect of S-100 on the nucleation and, probably, on the elongation of microtubules (MTs) as the pH raises. In the presence of microM Ca2+ levels, the ability of S-100 to disassemble MTs also increases linearly with the pH, suggesting that the larger inhibitory effect of S-100 on MTP assembly at alkaline than at acidic pH may depend on both a decrease in the assembly rate and an increase in the disassembly rate. Also, S-100 inhibits the assembly of phosphocellulose-purified tubulin to a larger and larger extent as the pH raises. S-100 brings about its effect on MT assembly-disassembly probably by sequestering soluble tubulin, though additional mechanisms cannot be excluded. The present data are briefly discussed in relation to the role attributed to changes in intracellular pH in the regulation of the state of assembly of cytoplasmic MTs.

Quantitative analysis of the interaction between S-100 proteins and brain tubulin

S-100 was shown to regulate the in vitro assembly of brain microtubule proteins (MTPs) in a Ca2+-mediated way by acting on both the nucleation and the elongation of microtubules (MTs). Here data will be shown suggesting that S-100 binds to tubulin. The binding is time-, temperature-, Ca2+-, and pH-dependent, and saturable with respect to S-100. At pH 6.75, the saturation curve is biphasic, displaying a high affinity component (dissociation constant, Kd1, approximately 0.1 microM) and a low affinity component (Kd2 approximately 3.8 microM). At pH 6.75, as the free Ca2+ concentration raises from 0 to 100 microM, the overall binding capacity increases from 0.065 to 0.66 mol S-100/mol tubulin dimer. This finding, together with the observation that the S-100 effect on MTP assembly is Ca2+-dependent at that pH, suggests that the S-100-induced inhibition of MTP assembly depends on S-100 binding to the low affinity sites on the tubulin molecule. The S-100 binding to tubulin is pH-dependent; as the pH raises from 6.75 to 8.3, both binding components are affected, the major changes consisting of an increase in the binding capacity and a decrease in the overall affinity. Moreover, as the pH raises, Ca2+ is no longer required for S-100 to bind to tubulin. S-100 also interacts with a component of whole MTPs (probably tubulin, on the basis of the above results). No S-100 binding to microtubule-associated proteins (MAPs) could be evidenced by the techniques employed in this study. On the contrary, some competition between S-100 and MAPs for binding sites or tubulin seems to occur.

Calcium-binding proteins in carcinoma, neuroblastoma and glioma cell lines

Antisera against the Ca2+-binding proteins parvalbumin, calbindin D-28K, and the S-100 proteins were used to study the distribution of their target proteins in selected human carcinoma (LICR-HN6;Caco-2), mouse neuroblastoma (clone NB-2a), and rat glioma cell lines (clone C-6). Pronounced staining with anti-parvalbumin was observed in the cytosol of all cells as well as in some nuclei, in particular, mitotic nuclei were highly immuno-reactive. Applying light and immune-electron microscopy (colloidal gold labelling) the parvalbumin-fluorescence was associated with filaments in the LICR-HN6 cells. However, this immunoreactivity was not a result of the presence of parvalbumin itself--as shown by biochemical analyses (HPLC, 2D-PAGE)--but was due to the presence of a Ca2+-binding and tumour-associated protein with similar biochemical and immunological properties. S-100 proteins were present in all tumour cell lines but their intracellular distribution was different from calbindin D-28K. Calbindin-immunoreactivity was found on the membranes of the carcinoma cell lines whereas neuroblastoma and glioma cells remained unlabelled. It is suggested that these proteins might be involved in the modulation of the enhanced stimulation of Ca2+-dependent processes occurring in tumour cells.