A comparison of cerebrosides, proteolipid proteins, and cholesterol as indices of myelin in the architecture of rat cerebrum

Abstract— —Serial frozen section sampling and microspectrophotometric assays were used to compare the fidelity of cerebrosides, proteolipid proteins (PLP) and cholesterol as indices of myelinated fibres in the somatosensory region of rat cerebrum. Cerebrosides (including sulphatides) were a satisfactory index regardless of the mode of expression. Per unit dry wt., they were lowest in layer II (4 per cent) and increased with the subpial depth to 16 percent in white matter. Elevations were seen at the locations of: the outer tangential plexus (1); the stripe of Kaes-Bechterew (2); the outer and inner stripes of Baillarger (3,4); and the inner tangential plexus (5), respectively. Expression in terms of residue protein, total lipid or DNA gave somewhat sharper profiles of the myeloarchitecture. PLP per unit dry wt. were lowest in layers I, II and III (2 per cent) and increased to 5·5 per cent in white matter. Peaks occurred near (3), (4) and (5). The PLP per cell and per unit residue protein rose six-fold, from the upper layers of cortex to white matter, and depicted the myeloarchitecture more faithfully. In general outline, PLP paralleled cerebrosides in distribution, in contrast with previous findings in human prefrontal cortex. Human cortex may contain more non-myelin PLP in the upper cortical layers owing to its greater wealth of neuropil and synapses. Cholesterol per unit dry weight was a poor index of the myeloarchitecture; it was lowest in layer II (5 per cent) and increased to 13-5 per cent in white matter without revealing the five horizontal bands of myelinated fibres. Expression of cholesterol in terms of total lipid or DNA improved its value as an index, but it was less satisfactory than cerebrosides.     

Changes in the sciatic nerve of the rabbit and its tissue constituents during development

Abstract— A segment, defined by gross anatomic boundaries, which comprises most of the sciatic nerve was dissected from rabbits aged from birth to 1 yr. The mean and standard deviation of the variance determined for the weights of pairs of nerve units removed from single animals of an age group did not exceed 2·7 per cent and 12·3 per cent respectively of the average weight of the two nerve units which were the values determined for a group of newborn animals. During the period from birth to one year of age, the weight and length of the nerve unit increased 47- and 6-fold respectively while the animal's weight increased 78-fold. Whereas the nerve unit length increased little after 8 weeks, its weight and that of the whole animal continued to increase up to 1 year. Estimations of nucleic acids in the nerve unit from adult animals gave values of 54 μg DNA-P and 25 μg RNA-P per g fresh weight. During the period birth to 1 yr the absolute amount of DNA in the nerve unit increased 11-fold, 71 per cent of this having occurred by 6 weeks of age. The absolute amount of RNA increased 11 -fold by 8 weeks of age and remained constant thereafter. During the period birth to 1 yr, the proportion of the nerve constituents accounted for by lipid-free solids remained constant at 10 per cent, while lipids increased from 5 to 18 per cent and tissue water declined from 84 to 71 per cent. Changes in some lipid classes were examined also. Increases of absolute content in the nerve unit over the first year and concentrations on a fresh weight basis attained in year-old animals were as follows: cholesterol, 132-fold and 86 mg/g; triglyceride 554-fold and 43·2 mg/g; total phospholipid, 85-fold and 61 mg/g; cerebroside 205-fold and 28 μmol/g; sulphatide, 154-fold and 10 μmol/g; monogalactosyl diglyceride, 31-fold and 0·6 μmol/g. The ratio cholesterol/phospholipid/galactolipid in whole nerve units from adult animals was 2·0/2·1/1·0 and the change in this ratio in the first year was compatible with enrichment of myelin in galactolipid during myelination. The ratio of cerebroside to sulphatide increased from 2·0 to 2·6 during this period. Increases in absolute content and concentrations attained for sialic acid-containing components representing cell surface constituents were as follows: ganglioside sialic acid, 33-fold, and 83 μg/g; glycoprotein sialic acid, 57-fold and 371 μg/g. The quantitative pattern of ganglioside fractions separated by thin-layer chromatography in one direction resembled that of whole brain and was the same at all ages studied. The changes reported reflect a composite picture of changes in a variety of cell membranes indicative of marked variation during development in quantity and composition of membranes.     

GANGLIOSIDES OF HUMAN MYELIN: SIALOSYLGALACTOSYLCERAMIDE (G7) AS A MAJOR COMPONENT

Abstract— Gangliosides were isolated from purified human myelin in a yield of 62 μg of lipid-bound sialic acid per 100 mg of dry myelin. Sialosylgalactosyl ceramide (G₇) was found to be a major component of the ganglioside fraction, amounting to 15 per cent of the total sialic acid. It accounted for 10 per cent of lipid-bound sialic acid in adult human white matter, making it the third most abundant ganglioside on a molar basis. These results were obtained with an improved method for isolating total gangliosides in high yield, by employing DEAE-Sephadex column chromatography. Myelin from other mammalian species had considerably less G₇, and there were also indications of maturational changes. Both 2-hydroxy and unsubstituted fatty acids were components of the ceramide unit, in a ratio of 3:2, respectively. The overall fatty acid pattern was very similar to that for myelin cerebroside and sulphatide. Long-chain bases included only C₁₈ species, with sphingosine predominating (>90 per cent). These observations suggest a metabolic relationship between G₇ and either cerebroside or sulphatide.     

Lipid composition in postnatal methylazoxymethanol-treated swiss albino mouse cerebellum.

Postnatal Swiss albino mice were treated with with methylazoxymethanol acetate (MAM) or saline and sacrificed at 25 days of age. Granule cell depletion resulted. Significant reduction in the cerebellar weight, protein, ganglioside sialic acid , cerebrosides, sulfatides, and phospholipids were documented. There was not, however, selective reduction of any component known to be associated with the synaptic structures. Specific association of cerebellar ganglioside with its granule cell population was not substantiated. Cerebroside/sulfatide ratios were not different in the two groups, indicating that significant alterations previously observed in spinal cord were not present in the cerebellum. It was concluded that the bulk of cerebellar granule cells and their synaptic connections could be deleted without affecting total ganglioside and phospholipid concentrations.     

Mitochondrial autonomy. Sialic acid residues on the surface of isolated rat cerebral cortex and liver mitochondria

N-acetylneuraminic acid at the surfaces of rat cerebral cortex and liver mitochondria and derived mitoplasts (inner membrane plus matrix particles) was studied biochemically and electrokinetically. Rat cerebral cortex mitochondria in 0.0145 M NaCl, 4.5% sorbitol, pH 7.2 ± 0.1, 0.6 mM NaHCO₃, had an electrophoretic mobility of - 2.88 ± 0.01 µ/sec per v per cm. In the same solution the electrophoretic mobility of rat liver mitochondria was - 2.01 ± 0.02, of rat liver mitoplasts was - 1.22 ± 0.07, and of rat cerebral cortex mitoplasts - 0.91 ± 0.04 µ/sec per v per cm. Treatment of these particles with 50 µg neuraminidase/mg particle protein resulted in the following electrophoretic mobilities in µ/sec per v per cm: rat cerebral cortex mitochondria, - 2.27; rat liver mitochondria, - 1.40; rat cerebral cortex mitoplasts, - 0.78; and rat liver mitoplasts, - 1.10. Rat liver mitochondria, mitoplasts, and outer mitochondrial membranes contained 2.0, 1.1, and 4.1 nmoles of sialic acid/mg protein, respectively. 10% of the liver mitochondrial protein and 27.5% of the sialic acid was solubilized in the mitoplast and outer membrane isolation procedure. Rat cerebral cortex mitochondria, mitoplasts, and outer mitochondrial membranes contained 3.1, 0.8, and 6.2 nmoles sialic acid/mg protein, respectively; 10% of the brain mitochondrial protein and 49 % of the sialic acid was solubilized in the mitoplast and outer membrane isolation solution procedure. Treatment of both the rat liver and cerebral cortex mitochondria with 50 µg neuraminidase (dry weight) /mg protein resulted in the release of about 50% of the available outer membrane sialic acid residues. Treatment of all of the particles with trypsin caused release of sialic acid but did not greatly affect the particle electrophoretic mobility. In each instance, curves of pH vs. electrophoretic mobility indicated that the particle surface contained an acid dissociable group, most likely a carboxyl group of sialic acid with pK_a ∼ 2.7. Treatment of either the rat liver or the cerebral cortex mitochondria with trypsinized concanavalin A did not affect the particle electrophoretic mobility but did cause a decrease in the electrophoretic mobility of L5178Y mouse leukemic cells.     

The effects of development on activity, specificity and endogenous substrates of synaptic membrane sialidase

Synaptic plasma membranes were prepared from cortices of rats varying in post-natal age between 4 and 30 days. Sialic acid associated with synaptic plasma membrane glycoproteins and gangliosides increased 75% and 50%, respectively, between 4 and 30 days. The amount of sialic acid released from these membrane constituents by intrinsic synaptic sialidase increased 2-4-fold over the same period. Incubation of synaptic plasma membranes with exogenous gangliosides or glycopeptides demonstrated a 2-3-fold increase in sialidase activity during development. The major gangliosides present in synaptic plasma membranes at all ages were GT1, GD1a, GD1b and GM1. Intrinsic sialidase hydrolyzed 50-70% of endogenous GT1 and GD1a gangliosides at all ages. Endogenous GD1b ganglioside was poorly hydrolyzed in young rats and its susceptibility to enzymic hydrolysis increased during development. When exogenous GD1a and GD1b were used as substrates a preferential increase in activity against GD1b occurred during development, the ratio of activity (GD1a/GD1b) decreasing from 3.6 to 1.6 between 7 and 30 days. 10- and 30-day-old synaptic plasma membranes contained complex mixtures of sialoglycoproteins, an increase in the relative concentrations of lower molecular weight sialoglycoproteins occurring during development. Intrinsic sialidase present in 10- and 30-day-old synaptic plasma membranes acted upon all molecular weight classes of sialoglycoproteins.     

DEVELOPMENTAL PROFILES OF GANGLIOSIDES IN HUMAN AND RAT BRAIN

Abstract— The developmental profiles of individual gangliosides of human brain were compared with those of rat brain. Interest was focused mainly on the pre- and early postnatal development. Human frontal lobe cortex covering the period from 10 foetal weeks to adult age and the cerebrum of rat from birth to 21 days were analysed. Lipid-NANA and lipid-P were followed; in the rat, also protein and brain weight. A limited number of samples of human cerebral white matter and cerebellar cortex were also studied. The following major results were obtained:

• 1 The ganglioside concentration increased approximately three-fold within a short period: in rat cerebrum, from birth to the 17th day; in human cerebral cortex, from the 15th foetal week to the age of about 6 months. The largest increase in the rat brain occurred by the 11th to the 13th day; in human brain by term. The relative increase of gangliosides during this period was more rapid than that of phospholipids.
• 2 A hitherto unknown distinct early period of ganglioside and phospholipid formation in rat occurred by the second to fourth day.
• 3 The changes in brain ganglioside pattern, characteristic of the developmental stages of the rat, were found to be equally pronounced in the human brain.
• 4 Regional developmental differences in the ganglioside pattern were demonstrated in human brain. A characteristic white matter pattern, rich in monosialogangliosides, had developed by the age of 1 year. The increase in ganglioside concentration and the formation of the definitive ganglioside pattern of cerebellar cortex occurred later than in cerebral cortex. This cerebellar pattern was characterized by a very large trisialoganglioside fraction.
• 5 The two periods of rapid ganglioside metabolism in rat brain preceded the two periods of rapid protein biosynthesis.

     

A monoclonal antibody recognizes an O-acylated sialic acid in a human melanoma-associated ganglioside

Monoclonal antibody D1.1 originally prepared against the B49 cell line derived from a rat brain tumor was shown to react with a ganglioside present in fetal rat brain. We have found that this antigen is also present in human malignant melanoma tumors as well as many melanoma cell lines. The ganglioside from human melanoma cell lines migrates between GM1 and GM2 on one-dimensional thin layer chromatography. Analysis by two-dimensional thin layer chromatography with intermediate ammonia treatment suggests that the ganglioside contains one or more base-labile O-acyl esters. Mild base hydrolysis under conditions known to remove O-acyl esters results in complete loss of antigenic reactivity. Thus, the alkali-labile moiety is a critical component of the epitope recognized by the antibody. Analysis of the sialic acids of total gangliosides from [6-3H]glucosamine-labeled melanoma cells showed that approximately 10% of these molecules are O-acylated. Similar analysis of the purified ganglioside showed that greater than 30% of the sialic acids comigrated with authentic 9-O-acetyl-N-acetylneuraminic acid. The antibody did not cross-react with normal human skin melanocytes nor with any of a large number of normal human adult and fetal tissues. The antibody also did not react with numerous other malignant cell lines studied. These findings suggest that the antigenic epitope defined by antibody D1.1 contains an O-acylated sialic acid and may arise from aberrant O-acetylation occurring in human malignant melanoma cells.     

Inhibitory effects of gangliosides on immune reactions of antibodies to neutral glycolipids in liposomes

Specific immune damage to liposomes containing Forssman or globoside glycolipid was inhibited when the liposomes also contained ganglioside. The activity of a human monoclonal Waldenstr?m macroglobulin antibody to Forssman glycolipid was inhibited by each of three gangliosides tested, GM3, GD1a and GD1b. Inhibition of the monoclonal antibody was dependent on the amount of ganglioside in the liposomes, and was diminished by reducing the relative amount of ganglioside. Inhibition also correlated positively with the number of ganglioside sialic acid groups, with inhibition by GT1b greater than GD1a greater than GM3. Naturally occurring human antibodies to globoside glycolipid were detected in 18% (9 out of 50) of normal human sera tested. Immune damage to liposomes induced by each of the three highest-reacting human anti-globoside sera was blocked by liposomal GM3. We conclude that gangliosides can strongly influence immune damage to membranes induced by antibody interactions with adjacent neutral glycolipids.     

Purification and structural characterization of de-N-acetylated form of GD3 ganglioside present in human melanoma tumors

The presence of gangliosides containing de-N-acetylated sialic acids in human tissues has been so far shown by using mouse monoclonal antibodies specific for the de-N-acetylated forms, but the isolation and chemical characterization of such compounds have not yet been performed. Since indirect evidence suggested that de-N-acetylGD3 ganglioside could be present in human melanoma tumors, we analyzed the gangliosides purified from a 500-g pool of those tumors. The de-N-acetylGD3 that was found to migrate just below GD2 in thin-layer chromatography was isolated from the disialogangliosides by high-pressure liquid chromatography using the specific antibody SGR37 to monitor the elution. The amount of antigen was found to be 320 ng per gram of fresh tumor or 0.1% of total gangliosides. Gas chromatography-mass spectrometry analysis of the antibody-positive ganglioside showed that sialic acids were formed of one molecule of N-acetylneuraminic acid and one molecule of neuraminic acid. Radioactive re-N-acetylation of the antigen yielded a GD3-like ganglioside with the radioactive label on the external sialic acid. The constitutive fatty acids were found to differ markedly from those of GD3 and 9-O-acetylGD3 isolated from the same pool of tumors. The major fatty acids were C16:0 and C18:0 in de-N-acetylGD3, whereas GD3 and its 9-O-acetylated derivative contained a large amount of C24:1. These data show that de-N-acetylGD3 ganglioside is indeed present in human melanoma tumors, and the fatty acid content suggests the existence of a de-N-acetylase mostly active on the molecular species of gangliosides with short-chain fatty acids.     

Myelination in rat brain: method of myelin isolation

Abstract— A procedure is described for the preparation from rat brain of myelin having the same degree of purity at all ages. Such a procedure is essential for the study of myelin composition during development. Microsomal contamination was successfully eliminated by adjusting the method to maintain a constant amount of brain per unit volume in the initial density gradient step, and by including two osmotic shocks and two low-speed centrifugation steps. Myelin prepared in this way from animals ranging from 15 days to 14months of age had a total ATPase activity of 0.3-2.0 μmol of P_i.h^?1.mg^?1 dry wt of myelin, representing 0.1-1.2 per cent recovery of the total homogenate activity; a Na⁺, K⁺- ATPase activity of 0.1-1.6 μfnol of P_i.h^?1.mg^?1 dry wt, representing 0.04-1.5 per cent recovery; a nucleic acid content of 0.2-0.7 per cent of myelin dry wt, representing 0.2-2.0 per cent recovery; and a ganglioside NANA content of 0.04-0.07 per cent of myelin dry wt. representing 0.2-4.6 per cent recovery. The myelin prepared from 20-day animals had the highest content of the first three constituents; otherwise the values of the four constituents were relatively constant per unit weight of myelin. The amounts of nucleic acid and ganglioside recovered in the myelin fractions increased with increasing age and myelin yield.     

DNA and RNA and the cytoarchitecture of human frontal cortex

DNA and RNA were studied in the layers of human prefrontal cortex by quantitative microchemical analyses on microtome-prepared serial frozen sections. Eleven cortical specimens from six autopsy brains were assayed. The mean total number of cells per mm³ of fresh cortex was estimated from DNA values. The number in layer I (61,000) was falsely high because of the inclusion of cells from the pia mater. From a plateau of 82,000-86,000 in layers II, IIIa and IIIb, the number of cells rose to 91,000 and 113,000 in layers IIIc and IV, respectively. The mean number was slightly lower in layer V, then gradually rose through layer VI to 127,000 cells in white matter. Per unit dry weight, DNA and cells varied much less than per unit volume; values averaged 14 per cent higher in layers II and IV than in neighbouring layers and in white matter were 20 per cent lower than in layer I. Intracortical patterns of RNA and RNA/cell reflected chiefly the distribution of neuronal cell bodies. Per unit fresh volume, RNA roughly paralleled DNA in layers I-V; through layer VI and into white matter RNA declined as DNA rose, reflecting the decline in neurons and increasing predominance of glial cells of lower RNA content. Per unit dry weight, RNA rose 50 per cent from layer I to layer II; a plateau of high values extended through layers II-V, then RNA declined rapidly through layer VI to a level in white matter that was 28 per cent of the value in layer II. Mean RNA/cell in cortex was 9-8 pg, with a maximum in layer IIIb (11.4 pg); in subcortical white matter it was 5.3 pg.     

Molecular basis for tetanus toxin coreceptor interactions

Tetanus toxin (TeNT) elicits spastic paralysis through the cleavage of vesicle-associated membrane protein-2 (VAMP-2) in neurons at the interneuronal junction of the central nervous system. While TeNT retrograde traffics from peripheral nerve endings to the interneuronal junction, there is limited understanding of the neuronal receptors utilized by tetanus toxin for the initial entry into nerve cells. Earlier studies implicated a coreceptor for tetanus toxin entry into neurons: a ganglioside binding pocket and a sialic acid binding pocket and that GT1b bound to each pocket. In this study, a solid phase assay characterized the ganglioside binding specificity and functional properties of both carbohydrate binding pockets of TeNT. The ganglioside binding pocket recognized the ganglioside sugar backbone, Gal-GalNAc, independent of sialic acid-(5) and sialic acid-(7) and GM1a was an optimal substrate for this pocket, while the sialic acid binding pocket recognized sialic acid-(5) and sialic acid-(7) with "b"series of gangliosides preferred relative to "a" series gangliosides. The high-affinity binding of gangliosides to TeNT HCR required functional ganglioside and sialic acid binding pockets, supporting synergistic binding to coreceptors. This analysis provides a model for how tetanus toxin utilizes coreceptors for high-affinity binding to neurons.     

Developmental Changes in the Biosynthesis of Sialoglycoprotein Substrates for Intrinsic Synaptic Sialidase

Abstract: N′-Acetyl-d -[6-³H]mannosamine was administered to 13- and 28-day-old rats by intraventricular injection. At various time intervals following the injection, synaptic membranes were prepared and the incorporation of radiolabel into sialic acid residues released from endogenous glycoproteins and gangliosides by intrinsic sialidase determined. Radiolabel was incorporated into synaptic membrane gangliosides and glycoproteins, and at all times tested, >90% of the label was associated with sialic acid. Sialic acid released from endogenous glycoproteins by intrinsic sialidase present in 28-day membranes incorporated only 20–25% as much radiolabel per nmole as sialic acid released by mild acid hydrolysis or by exogenous neuraminidase. In contrast, sialic acid released from glycoproteins present in 13-day-old membranes by intrinsic sialidase, mild acid hydrolysis, or exogenous neuraminidase all were similarly labelled. At both ages the specific radioactivity (cpm/nmol) of sialic acid released from gangliosides by the intrinsic enzyme was similar to the total ganglioside sialic acid released by mild acid hydrolysis. The results identify glycoprotein substrates for intrinsic synaptic membrane sialidase as a distinct metabolic class in the mature brain and suggest the occurrence of a developmentally related change in the metabolism of these glycoproteins.     

Effects of Cell Density on Lipids of Human Glioma and Fetal Neural Cells

Abstract: Gangliosides, phospholipids, and cholesterol of human glioma (12-18) and fetal neural cells (CH) were analyzed at specified cell densities, from sparse to confluent. Total ganglioside sialic acid, phospholipid phosphorus, and cholesterol increased in the glioma cells on a per cell, mg protein, or mg total lipid basis two- to threefold as cell density increased 25-fold. These same three constituents in the fetal cells increased with cell density on a per cell and mg protein basis but not on a per mg total lipid basis. In glioma cells, the di- and trisialogangliosides (GD₂+ GD_lb+ GT₁) increased from 1–2% of total ganglioside sialic acid at sparse densities to 7–8% at intermediate (logarithmic phase) densities to 10–13% at confluent densities. The set of simpler gangliosides (GM₄+ GM₃+ GM₂) decreased from 50% of total ganglioside sialic acid at sparse glioma cell densities, to 36% at intermediate and 30% at confluent densities. In the fetal neural cells, the set of gangliosides (GM₄+ GM₃+ GM₂) had about 48% of total ganglioside sialic acid in both sparse and confluent preparations. The fetal cells were twofold higher in GM₃ (32.4 ± 2.1%) than the glioma cells (16.8 ± 1.6%), but lower in GM_t (9.1 ± 0.9% versus 18.2 ± 1.8%), cell densities notwithstanding. Confluent cell preparations of both cell lines were consistently higher in ethanolamine plasmalogen than sparse cells. We conclude that in these two neural cell lines quantitative changes in ganglioside and phospholipid species occurred correlatively as cell densities increased. Higher glioma cell densities were associated with greater proportions of complex ganglioside species. These changes in cell membrane constituents during growth may result from cell contact and may indicate a role for them in cell growth regulation and/or differentiation.     

Increased brain capillaries in chronic hypoxia.

The effect of chronic hypobaric hypoxia (28 days, 455 Torr) on the organization of brain vessels was studied in Balb/c mice. In comparison to age-matched controls kept at sea level, emulsion-perfused capillaries in hypoxic mice showed marked dilation in all brain areas studied. Capillary length per unit volume of tissue (Lv) was increased in the cerebellar granular layer, the caudate nucleus, the globus pallidus, the substantia nigra, the superior colliculus, and the dentate gyrus. There was a selective increase of Lv in the hippocampus (CA1 strata pyramidale and lacunosum and CA3 strata pyramidale and oriens) and in somatosensory cortex layers V and VI, motor cortex layers II, III, V, and VI, and auditory cortex layers II and III. An increase in capillary surface area per unit volume of tissue was also determined in several brain areas, including layer IV of somatosensory cortex, where Lv was not significantly increased. The O2 diffusion conductance and PO2 in the tissues were estimated with a mathematical model. The remodeling of capillary diameter and length during chronic hypoxia accounts for the significant increase of O2 conductance to neural tissues. Also the estimated tissue PO2 in chronic brain hypoxia is markedly increased in the caudate nucleus and the substantia nigra compared with acute hypoxia. These results suggest that formation of new capillaries is an important mechanism to restore the O2 deficit in chronic brain hypoxia and that local rates of energy utilization may influence angiogenesis in different areas of the brain.     

THE REGIONAL DISTRIBUTION OF SIALOGLYCOPROTEINS, GANGLIOSIDES AND SIALIDASE IN BOVINE BRAIN

Abstract— Sialoglycoproteins and gangliosides were characterized in various bovine brain regions by determining the amount of sialic acid. Expressed per g dry weight, the gangliosidic sialic acid ranged from 11·20 to 1·93 μmol and the glycoprotein sialic acid from 8·93 to 1·84 μmol in grey and white matter respectively (values not corrected for incomplete release and breakdown during hydrolysis). Both the sialoglycoproteins and the gangliosides occur in highest concentration in areas predominating in neuronal cell bodies (cerebral grey, cerebellar grey, caudate nucleus). The lowest concentrations are found in those areas, consisting largely of myelinated fibre tracts and glial cells (pons, medulla, corpus callosum, cerebral white). Relative to the gangliosides the sialoglycoproteins are somewhat more concentrated in white matter.
The sialidase activity was investigated with endogenous substrate as well as with additional gangliosides or sialoglycopeptides. In all conditions the activity was much greater in grey matter than in white matter. The regional sialidase distribution more or less parallels the distribution of sialic acid in the various regions. At high substrate level the sialoglycopeptides inhibit the sialidase activity. There are indications that gangliosides are a far better substrate for brain sialidase than glycoproteins or glycopeptides. The possible significance of this phenomenon is discussed.     

Complex Carbohydrate Composition of Large Dense-Cored Vesicles from Sympathetic Nerve

Highly purified noradrenergic, large, dense-cored vesicles were isolated from bovine sympathetic nerve endings by sucrose-D2O density gradient centrifugation. Their concentration of glycoprotein hexosamine and sialic acid was 6.6 and 3.9 mumol/100 mg lipid-free dry weight, respectively, values which are similar to those previously found in bovine chromaffin granules. However, whereas chromaffin granule glycoproteins are characterized by their high proportion of N-acetylgalactosamine-containing O-glycosidically-linked oligosaccharides (present in the chromogranins), such oligosaccharides accounted for only 17% of those in noradrenergic synaptic vesicle glycoproteins. Fractionation of N-3H-acetylated glycopeptides by sequential lectin affinity chromatography demonstrated that approximately two-thirds of the oligosaccharides were of the tri- and tetraantennary complex type, accompanied by 14% biantennary oligosaccharides and 3% high-mannose oligosaccharides. The vesicles had a relatively low concentration of chondroitin sulfate (less than 5% of that in chromaffin granules) but significant amounts of heparan sulfate (0.4 mumol N-acetylglucosamine/100 mg lipid-free dry weight). No hyaluronic acid was detected. The concentration of ganglioside sialic acid in the noradrenergic vesicles was approximately 1 mumol/100 mg lipid-free dry weight, which is significantly higher than that of a crude membrane mixture from which the vesicles were prepared; the ratio of N-acetyl- to N-glycolylneuraminic acid was 0.8. Several molecular species of gangliosides were detected by thin-layer chromatography, but most of these did not exactly comigrate with bovine brain gangliosides. Cholera toxin binding indicated that approximately half or less of the gangliosides belong to the gangliotetraose series.     

The content and composition of gangliosides in brain subcellular fractions of the frog Rana temporaria

Ganglioside distribution in various frog brain subcellular fractions (myelin, microsomes, mitochondria, synaptosomes, plasma membranes of nerve endings and synaptic vesicles) was investigated. The synaptosomes and plasma membranes of nerve endings were found to be the main places of ganglioside localization, ganglioside concentration being 2.42 and 1.79 times higher than that in homogenates. Gangliosides were shown to be present in synaptic vesicles. The characteristic features of gangliosides from frog brain and its subcellular fractions are the predominance of polysialogangliosides with 3-5 sialic acid residues (up to 57.4%), low content of monosialogangliosides (not more than 7%) and the presence of disialogangliosides with short carbohydrate chain. The increase of ganglioside content per one nerve cell during phylogenetic development of vertebrates is discussed.     

Systematic position of fish species and ganglioside composition and content

The ganglioside content in brain of cartilaginous and bony fishes studied varies from 110 to 581 and from 104 to 595 micrograms sialic acid per g of wet weight respectively. A high degree of alkali lability and the predominance of C18-sphingosine and N-acetylneuraminic acid are typical of fish brain gangliosides. A high content of oligosialogangliosides with four and more residues of sialic acid and the predominance of gangliosides with gangliotetraosyl carbohydrate chain are characteristic for teleost brain. No pronounced difference was revealed in ganglioside composition and content of clupeomorphs and percomorphs. Gangliosides with short (lactosyl and gangliotriaosyl) carbohydrate chain predominate in brain of all cartilaginous fishes studied. A statistically significant difference was found in ganglioside content, relative oligosialoganglioside content and ganglioside fatty acid composition of squalomorphs and rajiformes, on one hand, and dasyatiformes and galeomorphs, on the other hand.