Interaction of calcium-binding proteins with calmodulin-dependent guanylate cyclase in Tetrahymena plasma membrane

Addition of bovine brain calmodulin and S-100 inhibited Tetrahymena calmodulin-induced stimulation of guanylate cyclase, but they did not affect enzymatic activity in the presence of calcium alone. Troponin C shows little effect on the cyclase activity regardless of the presence or absence of Tetrahymena calmodulin. The inhibitory effects of brain calmodulin and S-100 were overcome by the addition of Tetrahymena calmodulin, but not by calcium. Both calmodulins from Tetrahymena and bovine brain elicited stimulation of heart phosphodiesterase, while troponin C and S-100 did not affect the phosphodiesterase activity in the presence and absence of Tetrahymena calmodulin.     

Involvement of group S-100 brain specific proteins in the neurophysiological mechanisms of habituation

The possible role of S-100 brain specific proteins and their involvement in the neuronal mechanisms of habituation were investigated in identified neurons of the snail (Helix pomatia). Extracellular application and intracellular injection of antibodies into S-100 proteins caused a rapid and significant reduction of neuronal response to repeated stimulation compared with the control. A considerable reduction in the amplitude of evoked EPSP and an increase in the duration of latency of potentials was produced by the antibodies and numbers of action potentials declined. Meanwhile, membrane potential, membrane input impedance, and neuronal pacemaker potentials remained virtually unchanged. This effect is presumed to occur due to breakdown of synaptic transmission processes. The subject of possible involvement of S-100 proteins in the operation of synaptic structures as a primary apparatus for integrating neuronal activity is considered.P. K. Anokhin Institute of Normal and Pathological Physiology, Academy of Medical Sciences of the USSR, Moscow; Institute of Physiology, University of Novi-Sad, SFRYu. Translated from Neirofiziologiya, Vol. 19, No. 5, pp. 637–645, September–October, 1987.     

Modulation of tyrosine phosphorylation of p36 and other substrates by the S-100 protein

The inhibitory effects of Ca2+-binding proteins on tyrosine phosphorylation of p36 protein isolated from bovine intestinal epithelium by immunoprecipitated p130fps were investigated. S-100 protein dose dependently inhibited the p36 phosphorylation, and calmodulin weakly depressed the phosphorylation, whereas parvalbumin and troponin C had no significant effects. The S-100 preparation purified from bovine brain did not contain phosphatase activity or ATPase activity. The concentration of ATP did not affect the S-100-mediated inhibition of phosphorylation but the substrate protein, p36, reversed the inhibition. S-100 similarly inhibited the tyrosine phosphorylation of p36 by p60src but did not affect the p36 phosphorylation by protein kinase C. S-100 inhibited the tyrosine kinase activity of p130fps using the other substrates tested as well. These results suggest that S-100 interacts with the substrate binding site of retroviral tyrosine-specific protein kinases and may play a regulatory role in the tyrosine phosphorylation.     

Inherent behavioral activity of rats administered different fractions of brain-specific S-100 proteins

The intraventricular injection of brain specific S-100 proteins leads to the prolonged heterochronous changes of the inherent rat behaviour forms during the period of water and food needs restitution. The effects of various doses of S-100 proteins fractions on the behavioural activity differs in the degree of expression and in time of their onset. The specific influence of some S-100 proteins fractions on duration of the different inherent forms of rat behaviour can be explained by plurality of molecular mechanisms of their effects.     

S-100 proteins

S-100 is a group of closely related, small, acidic Ca2+-binding proteins (S-100a0, S-100a and S-100b, which are alpha alpha, alpha beta, and beta beta in composition, respectively). S-100 is structurally related to calmodulin and other Ca2+-binding proteins. S-100 is abundant in the brain and is contained in well defined cell types of both neuroectodermal and non-neuroectodermal origin, as well as in their neoplastic counterparts. In the mammalian brain, S-100a and S-100b are confined to glial cells, while S-100a0 is neuronal in localization. Single S-100 isoforms bind Ca2+ with nearly the same affinity. K+ antagonizes the binding of Ca2+ to high affinity sites on S-100. S-100 binds Zn2+ with high affinity. S-100 is found in a soluble and a membrane-bound form and has the ability to interact with artificial and natural membranes. S-100 has no enzymatic activity. S-100 has been involved in several activities including memory processes, regulation of diffusion of monovalent cations across membranes, modulation of the physical state of membranes, regulation of the phosphorylation of several proteins, control of the assembly-disassembly of microtubules. Some of these effects are strictly Ca2+-dependent, while other are not. S-100 is being secreted or released to the extracellular space. In some cases, this event is hormonally regulated. Several S-100 binding proteins are being described.     

Characterization of a membrane protein from cholinergic synaptic vesicles isolated from the electric organ of Torpedo marmorata

Rabbits were immunized with cholinergic synaptic vesicles isolated from the electric organ of Torpedo marmorata. The resultant antiserum had one major antibody activity against an antigen called the Torpedo vesicle antigen. This antigen could not be demonstrated in muscle, liver or blood and is therefore, suggested to be nervous-tissue specific. The vesicle antigen was quantified in various parts of the nervous system and in subcellular fractions of the electric organ of Torpedo marmorata and was found to be highly enriched in synaptic vesicle membranes. The antigen bound to concanavalin A, thereby demonstrating the presence of a carbohydrate moiety. By means of charge-shift electrophoresis, amphiphilicity was demonstrated, indicating that the Torpedo vesicle antigen is an intrinsic membrane protein. The antigen was immunochemically unrelated to other brain specific proteins such as 14-3-2, S-100, the glial fibrillary acidic protein and synaptin. Furthermore, it was unrelated to two other membrane proteins, the nicotinic acetylcholine receptor and acetylcholinesterase, present in Torpedo electric organ. The antiserum against Torpedo synaptic vesicles did not react with preparations of rat brain synaptic vesicles or ox adrenal medullary chromaffin granules.     

Modulation of brain protein phosphorylation by the S-100 protein

The effects of the nervous system specific protein, S-100, on protein phosphorylation in rat brain is examined. The S-100 protein inhibits the phosphorylation of several soluble brain proteins in a calcium dependent fashion. The most potent effect exhibited by S-100 was on the phosphorylation of a protein having a molecular weight of 73,000. The data suggest that the calcium binding S-100 protein, for which a function has not yet been assigned, may modulate calcium dependent phosphorylation of selected brain proteins.     

Calcium-independent, pH-regulated effects of S-100 proteins on assembly-disassembly of brain microtubule protein in vitro

At alkaline pH, Ca2+ is no longer required for S-100 proteins to inhibit the assembly and to promote the disassembly of brain microtubules in vitro, though the presence of Ca2+ significantly favors the S-100 effects. These effects are inversely related to the microtubule protein concentration and directly related to the S-100 concentration and the pH. Ca2+-independent, pH-regulated inhibition of assembly of phosphocellulose-purified tubulin by S-100 is also described. The microtubule disassembling effect of S-100 is additive to that of alkali (used to raise the pH), and S-100 further disassembles microtubules after alkalinization. Thus the larger inhibitory effect of S-100 on microtubule assembly at alkaline versus acid pH depends on both a decrease in the assembly rate and an increase in the disassembly rate. Together with previous data on this topic, the present findings indicate that S-100 proteins act on microtubule protein in vitro primarily by binding to tubulin, this event being Ca2+-regulated at a given pH, and pH-regulated at a given free Ca2+ concentration.     

Synaptic Vesicles from Mammalian Brain: Large-Scale Purification and Physical and Immunochemical Characterization

Purification of synaptic vesicles directly from homogenates of mammalian brain is compared with a classical method based on osmotic lysis of brain synaptosomes. The direct method affords increased yield and purity of synaptic vesicles prepared under isoosmotic conditions. Antigen SV2 and the antigens (primarily synaptophysin) recognized by rabbit antiserum R10, raised to purified rat brain synaptic vesicles, are localized specifically on approximately 40-nm-diameter microsomal vesicles from rat brain. Rat brain synaptic vesicles have equilibrium densities of approximately 1.11 g/ml on Nycodenz density gradients, 1.12 g/ml on glycerol/Nycodenz, and 1.07 g/ml on Ficoll gradients. Both SV2 and the R10 antigens are enriched approximately 50-fold in purified rat brain synaptic vesicles. Synaptic vesicles purified from rat or cow brain show active uptake of [3H]norepinephrine that is reserpine sensitive and dependent on ATP and Mg2+. Synaptic vesicles exhibiting [3H]norepinephrine uptake comigrate with approximately 40-nm-diameter synaptic vesicles carrying SV2 or R10 antigens during permeation chromatography. After the Sephacryl S-1000 chromatography step, [3H]-norepinephrine uptake activity is purified approximately 90-fold. Highly purified brain synaptic vesicles should facilitate studies at the molecular level of the roles of these organelles in neurotransmission at mammalian synapses.     

Identification of S-100 proteins and S-100-binding proteins in a detergent-resistant EDTA/KCl-extractable fraction from bovine brain membranes

The Triton X-100-resistant residue of brain membranes contains appreciable amounts of S-100 proteins. This fraction of S-100 can be solubilized by high concentrations of EDTA plus or minus high concentrations of KCl. Whereas KCl (0.6 M) extracts the detergent-resistant S-100, NaCl (1 M) does not. Endogenous Ca2+ is required and is sufficient for S-100 to remain associated with the detergent-resistant residue. However, 0.6 M KCl extracts a further fraction of Triton X-100-resistant S-100. In contrast, the Triton X-100-extractable fraction of S-100 resists the action of EDTA. These data suggest that Ca2+ regulates the extent of association of S-100 with Triton X-100-resistant components in brain membranes, whereas the association of S-100 with the lipid bilayer of brain membranes and/or with some intrinsic membrane proteins is less Ca2+-regulated. Several S-100-binding proteins are identified in the detergent-resistant residue of brain membranes by an overlay procedure.     

Expression of differentiated activities in reaggregated brain cell cultures.

Dissociated fetal mouse brain cells are allowed to reassociate in rotation culture to form aggregates. After several weeks these reaggregated brain cell cultures show markedly increased specific activities of monoamine oxidase, lactate dehydrogenase, and the brain-specific protein S-100, while catechol-O-methyltransferase activity increases slightly. Similar changes in these activities are found during mouse brain maturation. The amounts of monoamine oxidase, catechol-O-methyltransferase, and S-100 were also determined in surface cultures of fetal mouse brain cells, as well as glioma and neuroblastoma cell lines. The fetal brain and glial cell cultures possess much higher activities than the cultured neuroblastoma cells. However, lactate dehydrogenase activity was highest in the glioma and lowest in the surface cultures of fetal brain cells.     

S-100-Mediated Inhibition of Brain Protein Phosphorylation

The effects of the glial-specific, calcium-binding, S-100 protein on brain membrane and supernatant protein phosphorylation were assessed. S-100 concentrations as low as 5 micrograms/ml caused a marked inhibition of the phosphorylation of a soluble brain protein having a molecular weight of 73,000 daltons (73K). This protein was designated the S-100 protein-modulated phosphoprotein (SMP). Half-maximal inhibition of the phosphorylation of SMP by S-100 was obtained at concentrations of 12 micrograms/ml (0.57 microM). The inhibition of SMP phosphorylation by S-100 was calcium-dependent, with a calculated calcium Ka of 2.0 +/- 0.3 microM. SMP phosphorylation was also inhibited by calmodulin, but only partially and with a much lower potency. The inhibition of SMP phosphorylation by S-100 was not inhibited by fluphenazine, whereas the effect of calmodulin was. SMP was found in many brain areas, with the highest levels seen in the corpus callosum. Various peripheral tissues, such as kidney; liver; and pineal, pituitary, and adrenal glands, did not contain detectable SMP levels. At higher S-100 concentrations, greater than 10 micrograms/ml, the phosphorylation of several other soluble proteins was markedly inhibited. These proteins have molecular weights of 56K, 50K, and 47K. The phosphorylation of these proteins was enhanced by calmodulin. These data suggest that the S-100 protein may function to modulate the phosphorylation of brain proteins in a manner analogous to (although in a reciprocal fashion) that of calmodulin.     

Identity Between Cytoplasmic and Membrane-Bound S-100 Proteins Purified from Bovine and Rat Brain

Cytoplasmic and membrane-bound S-100 proteins were purified to homogeneity from bovine and rat brain. Cytoplasmic and membrane-bound S-100 from single species are identical by immunological, electrophoretic, spectrophotometric, and functional criteria. Cytoplasmic and membrane-bound S-100 from bovine brain consists of nearly equal amounts of S-100a and S-100b, whereas cytoplasmic and membrane-bound S-100 from rat brain consists mostly of S-100b. The functional role of membrane-bound S-100 remains to be elucidated.     

Quantitative alterations of S-100 protein and neuron specific enolase in the rat nervous system after chronic 2,5-hexanedione exposure

The regional changes in quantities of the glial S-100 protein and the neuron specific enolase in the rat nervous system have been studied after long-term exposure to 2,5-hexanedione. The wet weights of most of the examined nervous tissues were found to be reduced, with an extensive effect seen in the brain stem. Using dot immunobinding assays, the concentrations of S-100 were found to be increased in most of the examined tissues, but unaffected in the brain stem. The total amount of S-100 per tissue was markedly reduced in the brain stem. The content of neuron specific enolase was reduced only in the brain stem. Thus the effects of 2,5-hexanedione on the nervous system varied regionally. The brain stem was severely atrophied with a reduction of neuronal as well as of glial marker proteins. Other brain regions contained increased glial cell marker proteins as signs of progressive astroglial reactions.     

Calcium-sensitivity of brain microtubule proteins in the presence of S-100 proteins

In the presence of the usual 0.1 M Mes buffer, pH 6.7, mM free Ca2+ levels are required for half-maximal decrease in the rate and extent of brain microtubule protein (MTP) assembly in the absence of ox brain S-100, while microM free Ca2+ levels are sufficient in the presence of S-100. At the same pH 6.7, but in the presence of 0.12 M KCl, as low as 1.5 microM free Ca2+ is sufficient for S-100 to produce half-maximal reduction in the rate of assembly, while as high as 0.5 mM free Ca2+ is required in the absence of S-100. Similar results are obtained with rat brain S-100 (S-100b), indicating that single S-100 iso forms are equipotent in affecting the MTP assembly. At pH 7.5, MTPs are remarkably resistant to Ca2+ in the absence of S-100. In the presence of S-100, not only is the free Ca2+ concentration required for complete inhibition of assembly at least one order of magnitude smaller than that required in the absence of S-100, but significant S-100-dependent inhibition of assembly occurs in the absence of Ca2+. Under the two conditions where S-100 is particularly effective in inhibiting the assembly, i.e. at pH 6.7 in the presence of KCl and at pH 7.5, S-100 increases the disassembly rate even in the presence of microM Ca2+ levels. Our results suggest that the free Ca2+ concentration regulates the way S-100 disassembles microtubules (MTs): at microM Ca2+ levels, S-100 sequesters tubulin with concomitant increase in the disassembly rate; at mM Ca2+ levels, the S-100-Ca2+ complex probably interacts with MTs producing endwise disassembly.     

Specific Binding Sites for S-100 Protein in Isolated Brain Nuclei

Abstract: Isolated brain nuclei possess binding sites for S-100 protein. The interaction of S-100 with these sites is specific and time-, temperature-, and Ca⁺-dependent. The profile of the ¹²⁵I-labelled S-100 binding inhibition is biphasic, displaying a high-affinity component and a low-affinity component. The S-100 binding to brain nuclei is largely irreversible, probably owing to the formation of a tight complex between the protein and its nuclear binding sites. The S-100 binding to brain nuclei is in most aspects similar to that to synaptosomal membranes. Several lines of evidence indicate, however, that the S-100 binding to nuclei is not due to contamination of these structures with plasma membranes. Isolated liver nuclei do not possess the high-affinity component of S-100 binding.     

Regulatory effects of S-100 protein and parvalbumin on protein kinases and phosphoprotein phosphatases from brain and skeletal muscle

Summary In the eluted fractions of histone-treated crude extracts separated by Sephadex G-200 filtration, multiple protein kinase (PK) activities, including three from brain and two from skeletal muscle, were augmented by both S-100 protein and parvalbumin on the phosphorylation of endogenous substrates. One additional PK activity suppressed by both S-100 and parvalbumin was also found in muscle. In comparison, phosphoprotein phosphatases (PPase), which were also prepared by the same procedure of initial step of histone-treatment followed by the steps of Bio-Gel P-6DG for brain and DNA-cellulose for muscle, were all activated by S-100 while inhibited by parvalbumin and phosphatidylserine.     

Morphological alterations and increase of S-100 protein in cultured human glioma cells deprived of serum

Morphological alterations accompanied by an increase of the glia-specific protein S-100 have been shown to occur in a glial cell line (138 MG) of a human brain tumour if serum is removed from the culture medium. The glial S-100 protein was immunologically indistinguishable from S-100 present in human brain.     

Type A and type B monoamine oxidase activities in rat brain and liver mitochondria: a comparison of their properties using the non-ionic detergent Triton X-100

1. The effects of the non-ionic detergent Triton X-100 on the heterogeneity of monoamine oxidase activities were studied and compared in synaptic (fractions SM and SM2) and non-synaptic (fraction M) brain mitochondria and liver mitochondria. 2. Triton X-100 inhibited type A and type B monoamine oxidase activities in all four mitochondrial fractions in a concentration-dependent manner. Liver mitochondrial enzymatic activities were much more sensitive to this inhibition than those of brain mitochondria. The activities in the SM fraction of synaptic brain mitochondria were the least susceptible. 3. In all four mitochondrial fractions, type A activities were more sensitive to inhibition than type B activities. 4. These results suggest that the membrane micro-environment around the enzyme molecules in situ may be important in the functional expression of the activity of the enzyme.     

Purification and characterization of adipose tissue S-100b protein

We have purified S-100 protein from bovine brain using Ca2+-dependent affinity chromatography on N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide (W-7)-Sepharose (Endo, T., Tanaka, T., Isobe, T., Kasai, H., Okuyama, T., and Hidaka, H. (1981) J. Biol. Chem. 256, 12485-12489). By essentially the same procedure, W-7-Sepharose binding protein has been purified to apparent homogeneity from bovine abdominal adipose tissue. Electrophoretically, the purified protein from adipose tissue co-migrated with brain S-100b protein both in the presence and absence of sodium dodecyl sulfate and the protein was indistinguishable from brain S-100b region in terms of amino acid composition, two-dimensional tryptic peptide mapping and reactivity with anti-brain S-100b serum. Immunohistochemical analysis confirmed the existence of S-100b protein in the adipose cell where the protein seems to be located in both the nucleus and cytoplasm. Thus, the results indicate that the adipose cells contain the protein possibly identical with brain S-100b protein. In addition, the contents of S-100b protein in various rat tissues were measured by enzyme immunoassay method using the anti-bovine brain S-100b serum. Significant amounts of S-100b protein were found not only in the adipose tissue but also in the peripheral tissue such as trachea and skin. These observations suggest that S-100b protein should no longer be considered as a protein specific to nervous tissues.