Quantitative and qualitative variations in the glycoproteins in the chick embryo brain

Sugar content was examined in soluble and insoluble glycoproteins extracted from the chick embryo brain at different developmental stages. The content of hexosamines and uronic acids in the soluble fraction is higher during the whole period examined. The difference between the two fractions reaches a maximum at the 15th day. The insoluble fraction shows the highest content of sialic acid and fucose in comparison with the soluble one, especially toward hatching. The sialic acid/fucose ratio shows a different pattern in the two fractions examined, particularly in the soluble glycoproteins. The patterns of sialic acid and fucose indicate that quantitative and qualitative developmental changes occur in the soluble and insoluble glycoproteins. All sugars examined show significant changes on the 15th day, suggesting that this stage may represent a critical period in the development of the chick embryo brain.     

Effect of modification of synaptosomal membrane glycoproteins on adenylate cyclase activity

The effect of the modification of synaptosomal membrane glycoproteins on the activity of adenylate cyclase was studied. It was found that the binding of concanavalin A to unmodified guinea pig cerebral cortex synaptosomal membrane did not change adenylate cyclase activity. Concanavalin A binding to synaptosomal membrane of hypoxic brain cortex resulted in no decrease of enzyme activity. The level of protein-bound sialic acid in these synaptosomal fractions was 20% lower than in the control. Treatment of synaptosomal membranes with neuraminidase resulted in a decrease of sialic acid content by about 70%, but it had no significant effect on adenylate cyclase activity. The modification with concanvalin A of sugar end groups exposed by neuraminidase treatment resulted in significant decrease of both basal and fluoride-stimulated adenylate cyclase activity. These results seem to indicate that some component of the adenylate cyclase complex of brain synaptosomal membranes is closely interacting with a carbohydrate-containing macromolecule on the cell surface.This work was supported by, the Polish Academy of Sciences within the project 10.4.     

Neuraminidase activity and cell surface sialic acid turnover in Rous sarcoma virus transformed chick embryo fibroblasts

Neuraminidase activity of Rous sarcoma virus transformed chick embryo fibroblasts (RSV-CEF) was assayed using an exogenous substrate, neuraminlactitol-[3H], and endogenous, cell surface [14C]-N]-acetyl-neuraminic acid. RSV-CEF had higher neuraminidase activity toward both substrates than did chick embryo fibroblasts (CEF) or nontransformed, Rous associated virus infected CEF (RAV-CEF). The total sialic acid content of RSV-CEF was lower than CEF or RAV-CEF, and more of the total sialic acid was accessible to extracellular Clostridium perfringens neuraminidase. Activity of the enzymes synthesizing and degrading the substrate for sialyltransferase, cytidine-5'-monophosphate-N-acetyl-neuraminic acid (CMP-AcNeu) was measured in order to determine whether control of substrate levels for sialyltransferase might contribute to the decreased levels of glycoprotein bound sialic acid. No change in activity of these enzymes was found in RSV-CEF as compared to CEF or RAV-CEF.     

Single non-inactivating K+ channels in the myotubes of the chick embryo in tissue culture

Single-channel K+ currents were studied in the myotubes from the chick embryo grown in tissue culture for 4--9 days by employing the patch clamp technique. The "cell attached" configuration was used and the pipette was filled with a solution containing 3 mmol.l-1 K+. The channels exhibited a high conductance of approximately 90 pS and the probability of finding them open increased by an e-fold factor for 13 mV depolarization for low levels of activity. The channels did not inactivate during long-lasting depolarization. These channels have been suggested to contribute to delayed rectification.     

Development of gamma-glutamyl transpeptidase activity in primary cultures of neurones and glial cells derived from the cerebral hemispheres of chick embryos

The development of gamma-glutamyl transpeptidase (GGT) activity in neurones and glial cells was studied in primary cell cultures derived from the cerebral hemispheres of chick embryos. GGT activity was found in both basic types of nervous tissue cells. It was always higher in glial cell cultures, where it was up to 2.3-fold the values in neurone-enriched cultures. If the culture medium contained foetal calf serum, the GGT activity of both types of nerve cells was higher than in the presence of inactivated calf serum. Comparison with the in vivo situation showed that the level of GGT activity in nerve cell cultures was significantly lower. Between the seventh day of embryogenesis and the third day of postnatal development of the nerve cells, there were marked differences between the GGT activity of cells maintained under in vitro conditions and cells of the same age in brain tissue homogenate. GGT activity in cerebral hemisphere homogenates from a 17-day-old embryos amounted to 4-fold the activity in a primary glial cell culture and to 16-fold the value in a neurone-enriched culture from hemispheres at the same stage of development.     

Distribution and metabolism of glycoproteins and glycosaminoglycans in subcellular fractions of brain.

The distribution, carbohydrate composition, and metabolism of glycoproteins have been studied in mitochondria, microsomes, axons, and whole rat brain, as well as in various synaptosomal subfractions, including the soluble protein, mitochondria, and synaptic membranes. Approximately 90% of the brain glycoproteins occur in the particulate fraction, and they are present in particularly high amounts in synaptic and microsomal membranes, where the concentration of glycoprotein carbohydrate is 2-3% of the lipid-free dry weight. Treatment of purified synaptic membranes with 0.2% Triton X-100 extracted 70% of the glycoprotein carbohydrate but only 35% of the lipid-free protein residue, and the resulting synaptic membrane subfractions differed significantly in carbohydrate composition. The glycoproteins which are not extracted by Triton X-100 also have a more rapid turnover, as indicated by the 80-155% higher specific activity of hexosamine and sialic acid 1 day after labeling with [3H]glucosamine in vivo. The specific activity of sialic acid in the synaptosomal soluble glycoproteins 2 hr after labeling was greater than 100 times that of the synaptosomal particulate fraction, whereas the difference in hexosamine specific activity in these two fractions was only twofold, and by 22 hr there was little or no difference in the specific activities of sialic acid and hexosamine in synaptosomal soluble as compared to membrane glycoproteins. These data indicate that sialic acid may be added locally to synaptosomal soluble glycoproteins before there is significant labeling of nerve ending glycoproteins by axoplasmic transport. Fifty to sixty percent of the hyaluronic acid and heparan sulfate of brain is located in the various membranes comprising the microsomal fraction, whereas half of the chondroitin sulfate is soluble and only one-third is in microsomal membranes. When microsomes are subfractionated on a discontinuous density gradient over half of the hyaluronic acid and chondroitin sulfate are found in membranes with a density less than that of 0.5 M sucrose (representing a six- to sevenfold enrichment over their concentrations in the membranes applied to the gradient), whereas half of the heparan sulfate is present in membranes with a density greater than that of 0.8 M.     

The effects of L-2,4-diaminobutyric acid on the uptake of gamma-aminobutyric acid by a synaptosomal fraction from rat brain

l-2,4-diaminobutyric acid was studied as an inhibitor of gamma-aminobutyric acid uptake by a synaptosomal fraction isolated from rat brain. Competitive inhibition was observed during short-term exposure of the synaptosomal fraction to the inhibitor but noncompetitive inhibition was observed following prolonged exposure. Studies on the mode of action of l-2,4-diaminobutyric acid showed that the synaptosomal fraction was capable of accumulating this compound and that both the uptake and the effectiveness of the inhibitor were sodium-dependent and temperature-sensitive. In addition, the degree of inhibition of gamma-aminobutyric acid uptake was related to the amount of l-2,4-diaminobutyric acid accumulated. It is suggested that the observed noncompetitive inhibition of gamma-aminobutyric acid uptake by l-2,4-diaminobutyric acid is a result of the accumulation of the inhibitor which exerts its effect from within the synaptosomes. Raising the external concentration of gamma-aminobutyric acid to saturating levels did not completely inhibit the accumulation of l-2,4-diaminobutyric acid. Thus, the transport of l-2,4-diaminobutyric acid appears to be mediated, at least in part, by a carrier which is not involved in the transport of gamma-amiuobutyric acid.     

Angiostatic activity and metabolism of cortisol in the chorioallantoic membrane (CAM) of the chick embryo.

There is considerable interest in the discovery of compounds which inhibit angiogenesis dependent (neovascular) diseases. The chick embryo, due to the rapid development of an extensive vascular capillary network in the chorioallantoic membrane (CAM), has been used extensively as a model for studying angiogenesis. Angiostatic steroids are a new class of compounds which inhibit the growth of new capillaries in the chick CAM and in other models of neovascularization. Despite the potential therapeutic importance of these compounds, little is known about the ability of the CAM to metabolize these steroids. We have evaluated the ability of the chick CAM to metabolize cortisol which is both an angiostatic steroid as well as a glucocorticoid. When CAM homogenate was incubated with [3H]cortisol and NADPH at 37 degrees C and pH 7.4, and the reaction products analyzed by reverse phase HPLC, [3H]cortisol was converted exclusively to 20 beta-dihydrocortisol (4-pregnen-11 beta,17 alpha,20 beta,21-tetrol-3-one). The cortisol metabolite, 20 beta-dihydrocortisol, has very little glucocorticoid activity, but shows significant angiostatic activity in the CAM comparable to cortisol. The apparent Km determined for cortisol metabolism was 12 microM and the observed Vmax was 1.4 mumol cortisol/mg protein/min. The majority of the 20 beta-reductase activity was found in the soluble (242,000 g) fraction of CAM homogenate. 20 beta-Reductase activity in chick embryo CAM has not been previously reported.     

Sialic acid at the surface of myocardial cells during embryonic development

We tested the hypothesis that the reduction of automaticity during the embryonic development of chick ventricular myocytes is correlated with the number of sialic acid residues at the cell surface. The major findings were twofold. First, the sialic acid content of ventricular tissue fragments declined during the period between 4 and 17 days of development; however, when a 26% reduction of cell surface area was taken into account, the surface density of sialic acid at 7 and 17 days was not significantly different. Second, the sialic acid content of ventricular cell aggregates (after 3 days in gyratory culture) increased during the same two-week period. On the surface of these cells, the density was significantly greater at 17 days than at 7 days, even after a 17% increase in cell surface area had been taken into account. When the developmental increase in sialic acid content was compared with a concomitant decline in aggregate beat rates, we calculated a correlation coefficient of 0.85. Thus, while there could be some relationship between aggregate automaticity and sialic acid content, there appears to be no such correlation for fragments of chick ventricle.     

The effect of a synthetic tripeptide nervous tissue cultured in vitro]

Explants from chick embryo PNS (ganglion trigeminale) and from CNS of embryonal rats (hippocampus) and dissociated cells from chick embryo cerebral hemispheres were cultivated in maximow chambers in the presence of various concentrations of placental serum and of a chemically synthesized tripeptide Gly-His-Lys. 1. The presence of tripeptide in the nutrient medium with a low concentration of serum did not compensate the outgrowth of nerve fibers, that take place in the growth medium. 2. In the presence of tripeptide in the nutrient medium with low concentration of serum the index of growth area increased significantly. 3. Within the first days in cell cultures 0,01 microgram tripeptide pro ml medium stimulated the outgrowth of neuronal processes. 4. The experiments indicated, that the tripeptide did not replace the serum. The possible role of tripeptide as a system in controlling neuron-glial ratio in vitro is discussed.     

Subcellular distribution and activation by non-ionic detergents of guanylate cyclase in cerebral cortex of rat

Non-ionic detergents stimulated particulate guanylate cyclase activity in cerebral cortex of rat 8- to 12-fold while stimulation of soluble enzyme was 1.3- to 2.5-fold. Among various detergents, Lubrol PX was the most effective one. The subcellular distribution of guanylate cyclase activity was examined with or without 0.5% Lubrol PX. Without Lubrol PX two-thirds of the enzyme activity was detected in the soluble fraction. In the presence of Lubrol PX, however, two-thirds of guanylate cyclase activity was recovered in the crude mitochondrial fraction. Further fractionation revealed that most of the particulate guanylate cyclase activity was associated with synaptosomes. The sedimentation characteristic of the particulate guanylate cyclase activity was very close to those of choline acetyltransferase and acetylcholine esterase activities, two synaptosomal enzymes. When the crude mitochondrial fraction was subfractionated after osmotic shock, most of guanylate cyclase activity as assayed in the absence of Lubrol PX was released into the soluble fraction while the rest of the enzyme activity was tightly bound to synaptic membrane fractions. The total guanylate cyclase activity recovered in the synaptosomal soluble fraction was 6 to 7 times higher than that of the starting material. The specific enzyme activity reached more than 1000 pmol per min per mg protein, which was 35-fold higher than that of the starting material. The membrane bound guanylate cyclase activity was markedly stimulated by Lubrol PX. Guanylate cyclase activity in the synaptosomal soluble fraction, in contrast, was suppressed by the addition of Lubrol PX. The observation that most of guanylate cyclase activity was detected in synaptosomes, some of which was tightly bound to the synaptic membrane fraction upon hypoosmotic treatment, is consistent with the concept that cyclic GMP is involved in neural transmission.     

The organization of gangliosides and other lipid components in synaptosomal plasma membranes and modifying effects of calcium ion

Synaptosomes were prepared from bovine brain by zonal rotor sucrose density centrifugation. While a major fraction of lipid-bound sialic acid is included uniformly within the synaptosomal distribution profile, the sialoglycoproteins and some gangliosides do not follow this pattern, Exposure to extrasynaptosomal calcium results in alterations in the surface labeling properties of some gangliosides and membrane plasmalogens, suggesting that extrasynaptic Ca²⁺ may influence the conformation of complex lipids in synaptic plasma membranes. The level of intrinsic membrane-associated sialidase activity that liberates sialic acid from these sialoglycoconjugates parallels the synaptosomal buoyant density distribution profile, supporting a view that this enzyme resides in synaptosomal membranes in close association with a sialolipid substrate.     

ISOLATION AND PARTIAL CHARACTERIZATION OF FRACTIONS ENRICHED IN SYNAPTOSOMES FROM CHICK BRAIN

–From a pool of hemispheres, optic lobes and cerebellum of chick 3 fractions containing synaptosomes have been prepared. They were obtained by subcellular fractionation of a homogenate and centrifugation of a crude mitochondrial suspension on a discontinuous Ficoll density gradient in iso-osmoticsucrose. The synaptosomal fractions were isolated from bands at the interface of 5–9, 9–12 and 12–16% Ficoll. The characterization of these fractions by marker enzymes, such as lactate dehydrogenase, acetyl-cholinesterase, monoamine oxidase, acid phosphatase and rotenone-sensitive and -insensitive NADH: cytochrome c reductase is reported. Electron microscopic analyses showed that the first fraction (AB) at the 5–9% Ficoll interface contained myelin and other membrane fragments as well as synaptosomes, the second fraction (C) at the 9–12% Ficoll interface contained mainly synaptosomes, and the third fraction (D) at the 12–16% Ficoll interface contained synaptosomes and free mitochondria. A fourth fraction (E) was obtained as a pellet, and was enriched in free mitochondria. There was fair agreement between the distribution pattern of the marker enzyme activities and the particles of the fractions seen by electron microscopy. The content of glycoprotein-bound N-acetylneuraminic acid and total phospholipid of these fractions has been determined. Relative to the mitochondrial fraction (E) the synaptosome fraction contained on basis of particulate protein, respectively, 2–3 times as much protein-bound N-acetylneuraminic acid and 10–20 per cent more total phospholipid.     

Ganglioside, protein, hexose, and sialic acid changes in the trisected optic tectum of the chick embryo.

Spatiotemporal changes in membrane constituents of cells from the optic tectum of the chick embryo were analyzed during the period of maximum differentiation and synaptogenesis. Each tectum from 6-, 8-, 10-, and 12-day embryos was cut into three subregions along the topological gradient of differentiation. Electrophoretic analysis of proteins revealed an already complex population by Day 6 which remained relatively unchanged through later stages, with little if any topological variations. In contrast, chromatographic analysis of gangliosides showed an increasingly complex pattern as differentiation proceeded, with a growing preponderance of multisialogangliosides. Total membrane protein increased symmetrically with tissue mass in each subregion. However, hexose concentration and sialic acid/hexose ratios showed strikingly asymmetrical topological distributions as early as Day 8, and tended to fluctuate reversibly within brief (1 day or less) time periods. These results suggest that during the period of maximal differentiation and retino-tectal synaptogenesis in the optic tectum of the chick, the membrane protein population remains relatively stable and topologically invariant, whereas the polysaccharide chains of membrane macromolecules fluctuate according to topological position and developmental state in a complex, relatively rapid, and apparently oscillatory fashion.     

Binding of I-Concanavalin a and agglutination of embryonic neural retina cells : Age-dependent and experimental changes

Embryonic chick neural retina cells dissociated from retina tissue by treatment with EGTA (a calcium chelator) show an age-dependent decline in ability to agglutinate with concanavalin A (ConA). This developmental change in cell surface properties is not due to loss of ConA-binding sites, since mature retina cells can be rendered agglutinable by mild trypsinization. It is also not due to masking of ConA receptors, or to a decrease in their amount, since retina cells from late embryos (19 days) bind four times as much ¹²⁵I-ConA as cells from early embryos (8 days). Our findings lead us to suggest that, as the retina differentiates the lateral mobility of ConA receptors in the cell membrane decreases resulting in a reduction of cell agglutinability; trypsinization of late embryo retina cells increases the mobility of the receptors and thereby facilitates their clustering by the lectin into a configuration conducive to cell agglutination.The ability of late embryo (19 day) retina cells dispersed with EGTA to agglutinate with ConA could be increased by still other treatments: by pre-incubation of the cell suspension in Tyrode's balanced salt solution (1 h, 37 °C); and by brief pre-exposure to glutaraldehyde. These two treatments did not enhance cell agglutination with wheat germ agglutinin (WGA). Glutaraldehyde treatment of trypsinized cells made them agglutinable with ConA also at 4 °C; cells treated otherwise agglutinated only at higher temperature. Surface-saturation of monodispersed retina cells with ConA at 37 °C—but not at 4 °C—prevented their agglutination with this lectin, but not with WGA; this inhibition was reversible by methyl a-D-glucopyranoside (αMG).     

GUANYL CYCLASE IN CHICK EMBRYO BRAIN CELL CULTURES: EVIDENCE OF NEURONAL LOCALIZATION

Abstract— Guanyl cyclase activity was studied in dissociated chick embryo brain cell cultures presenting different ratios of neuronal to glial elements. The cultures containing neurons in substantial numbers always had higher guanyl cyclase activities than those consisting mainly of glial cells. No guanyl cyclase activity could be found in cultures made up of pure glial or meningeal cells. These results provide further evidence for our conclusion based on subcellular fractionation studies (G oridis & M organ , 1973), that brain guanyl cyclase might be overwhelmingly concentrated in neurons. Guanyl cyclase activity of chick embryo cerebral hemispheres increased sixfold between day 12 and day 16 after fertilization; an increase, though of much smaller magnitude, was also seen in cultured cells of the same age.     

Activation of guanylate cyclase in cerebral cortex of rat by hydroxylamine.

Hydroxylamine actived guanylate cyclase in particulate fraction of cerebral cortex of rat. Activation was most remarkable in crude mitochondrial fraction. When the crude mitochondrial fraction was subjected to osmotic shock and fractionated, guanylate cyclase activity recovered in the subfractions as assayed with hydroxylamine was only one-third of the starting material. Recombination of the soluble and the particulate fractions, however, restored guanylate cyclase activity to the same level as that of the starting material. When varying quantities of the particulate and soluble fractions were combined, enzyme activity was proportional to the quantity of the soluble fraction. Heating of the soluble or particulate fraction at 55 degrees for 5 min inactivated guanylate cyclase. The heated particulate fraction markedly activated guanylate cyclase activity in the native soluble fraction, while the heated soluble fraction did not stimulate enzyme activity in the particulate. The particulate fraction preincubated with hydroxylamine at 37 degrees for 5 min followed by washing activated guanylate cyclase activity in the soluble fraction in the absence of hydroxylamine. Further fractionation of the crude mitochondrial fraction revealed that the factor(s) needed for the activation by hydroxylamine is associated with the mitochondria. The mitochondrial fraction of cerebral cortex activated guanylate cyclase in supernatant of brain, liver, or kidney in the presence of hydroxylamine. The mitochondrial fraction prepared from liver or kidney, in turn, activated soluble guanylate cyclase in brain. Activation of guanylate cyclase by hydroxylamine was compared with that of sodium azide. Azide activated guanylate cyclase in the synaptosomal soluble fraction, while hydroxylamine inhibited it. The particulate fraction preincubated with azide followed by washing did not stimulate guanylate cyclase activity in the absence of azide. The activation of guanylate cyclase by hydroxylamine is not due to a change in the concentration of the substrate GTP, Addition of hydroxylamine did not alter the apparent Km value of guanylate cyclase for GTP. Guanylate cyclase became less dependent on manganese in the presence of hydroxylamine. Thus the activation of guanylate cyclase by hydroxylamine is due to the change in the Vmax of the reaction.     

The isolation and characterization of plasma membrane from cultured cells V. The chemical composition of plasma membranes isolated from chicken tumors initiated with virus-transformed cells

Sarcomas were initiated in chicken muscle and wing web by Bratislava 77 and morph^r Fujinami virus. Plasma membrane was isolated from the virus-induced tumor cells by differential centrifugation and flotation equilibrium centrifugation. The levels of neutral sugar and sialic acid in these isolated plasma membranes were very similar to the levels found in cultured chick embryo fibroblasts transformed in vitro with the same oncogenic viruses and differed markedly from the levels found in uninfected and leukosis virus-infected fibroblasts.The phospholipid content of the isolated cell membranes from tumors was less than the quantity of lipid found in the plasma membrane of cultured cells and differed with the site of the tumor. Breast muscle tumors contained less plasma membrane phospholipid than did wing tumors.The similarities in the neutral sugar and the sialic acid content of these two different sources of plasma membrane indicate that oncogenic transformation in cell culture reproduces in situ neoplastic change to a large extent, for at least this one parameter of cell surface change.     

Biosynthesis of chondroitin sulfate proteoglycan. Subcellular distribution of glycosyltransferases in embryonic chick brain.

The subcellular distributions of five glycoslytransferases involved in the biosynthesis of the chondroitin sulfate proteoglycan and of a sixth glycosyltransferase, presumably involved in glycoprotein biosynthesis, were examined in 13-day chick enbryo brain. Fractionation studies performed by the procedure of Gray and Whittaker (Gray, E.G., and Whittaker, V.P. (1962) J. Anat. (London) 96, 79-88) revealed that three of the six enzymes were directly associated with the membrane fraction of synaptosome-enriched preparations; varying amounts of the remaining glycosyltransferases were distributed between the 100,000 times g supernatant and the synaptosome-enriched fraction after differential and density gradient centrifugation of crude chick brain homogenates. The time of appearance of three of the glycosyltransferases was examined in chick embryo brain tissue at several stages of development. The brain content of each glycosyltransferase increased rapidly between day 7 and hatching at day 21. A sharp decline in each of the glycosyltransferase activities occurred at hatching.