Demyelination produced by experimental allergic neuritis serum and anti-galactocerebroside antiserum in CNS cultures. An ultrastructural study

Cultures of mouse cerebellum were exposed to sera from rabbits with experimental allergic neuritis induced by whole peripheral nerve immunization (WN-EAN) and to rabbit anti-galactocerebroside (GC) antisera, and were studied by electron microscopy. Both antisera produced almost identical demyelinative patterns. These consisted of large intramyelinic splittings, "smudged" changes of myelin, degeneration of oligodendrocytes, and phagocytosis of myelin by astrocytes, changes similar to those described after application of whole spinal cord-induced experimental allergic encephalomyelitis (WM-EAE) sera. In addition, patterns which have been considered more characteristic of in vivo demyelinative lesions have been found, susch as vesicular disruption of myelin lamellae and peeling off and phagocytosis of myelin by phagocytic mononuclear cells with electron dense cytoplasm. The morphologic similarities between demyelinative patterns in central nervous system (CNS) cultures induced by anti-GC antiserum and WN-EAN serum and WM-EAE serum, and the fact that elevated antibody titers to GC are found in sera from rabbits with WN-EAN and WM-EAE (Saida, et al., 1977), support the concept that anti-GC antibody is the major factor in the production of CNS demyelination in vitro by sera from rabbits with WN-EAN and WN-EAE.

Two gel states of cerebrosides. Calorimetric and Raman spectroscopic evidence

The enthalpy of the gel-to-liquid crystalline phase transition for kerasin (15.8 kcal/mol) is found to be markedly higher than that for phrenosin and unfractionated bovine brain cerebrosides (about 7 kcal/mol). Evidence for a higher degree of order in the hydrocarbon chains and a different configuration in the polar region of kerasin is supplied by Raman spectroscopic parameters for these gel phases. The high transition enthalpy for kerasin is ascribed to a lesser accommodation of gauche conformers in the hydrocarbon chains just below the transition temperature. The thermodynamic behavior of these cerebroside fractions, including hysteresis in kerasin gels, is compared to that previously reported for sphingomyelins.

Cerebroside sulfotransferase activity in human lung tissues. An elevated level in lung adenocarcinoma

Cerebroside sulfotransferase activity was demonstrated in particulate fractions from human lung and its carcinoma tissues. The activity in human lung adenocarcinoma was significantly higher than those in a different histological type of carcinoma (squamous cell carcinoma) and in normal tissue from which each carcinoma was derived.

Diminished cerebroside-sulfotransferase activity in the Jimpy mouse mutant due to altered lipid composition in microsomal membranes

The mouse mutant Jimpy shows a deficient myelination. In the microsomes of the Jimpy brain, the cerebroside-sulfotransferase (EC 2.8.2.11) activity is low. The cerebroside-sulfotransferase activity of Jimpy microsomes could be normalised by delipidating the microsomes with cold acetone and adding to them acetone-extracted lipids from normal microsomes. The lipids extracted from Jimpy membranes did not influence the cerebroside-sulfotransferase activity of neither normal nor Jimpy microsomes. The same results were obtained if artificial cholesterol-phospholipid mixtures in ratios corresponding to the ones found in normal and Jimpy membranes were used for recombination experiments. Therefore the diminished enzyme activities in Jimpy microsomes may be related to the lower cholesterol-phospholipid ratio found in the microsomal membranes of the Jimpy mutant.

The use of liposomes as acceptors for the assay of lipid glycosyltransferases from rat brain

Preparation and characterization of sonicated vesicles of various lipid composition containing hydroxy and normal fatty acid ceramides are reported. Such vesicles have been successfully used for the first time as acceptors for the assays of lipid glycosyltransferases, UDP-galactose:ceramide galactosyltransferase and UDPglucose: ceramide glucosyltransferase. Stability of the vesicles and the optimal enzyme activities were the criteria used to select the final composition of the vesicles. The activities of the glycosyltransferases were dependent not only on the appropriate assay conditions but also on the type and source of the phospholipids used to form the liposomes. Ceramides containing normal fatty acids were incorporated into phosphatidylcholine vesicles in a molar ratio of 1 : 3.4 and used as the acceptor for the assay of UDPglucose:ceramide glucostyltransferase. For the assay UDP-galactose:ceramide galactosyltransferase, vesicles were prepared by sonication of bovine brain ethanolamine phospholipids, phosphatidylcholine and ceramide containing alpha-hydroxy fatty acids, in a molar ratio of 6 : 0.57 : 1. The size of the vesicles as determined by electron microscopic measurement ranged mostly between 200--500 A. The results obtained by selective labelling of the outer surface amino groups with the membrane-impermeable reagent, 2,4,6-trinitrobenzenesulfonic acid, indicated that the ethanolamine phospholipid-containing liposomes consisted of closed vesicles. After incubation with the appropriate cofactors and labelled sugar nucleotides, the radioactive reaction products were shown to cochromatograph with the authentic standards by thin-layer chromatography and autoradiography.

Thermotropic behavior of monoglucocerebroside--dipalmitoylphosphatidylcholine multilamellar liposomes

The thermotropic behavior of multilamellar liposomes prepared from mixtures of glucocerebroside and dipalmitoylphosphatidylcholine has been studied by high-sensitivity scanning calorimetry. It is shown that glucocerebroside has a marked effect on the gel--liquid crystalline transition of dipalmitoylphosphatidylcholine. The pretransition seen in pure samples of dipalmitoylphosphatidylcholine is undetectable at small mode fractions of glucocerebrosides (less than 10%). The main transition is shifted to higher temperatures and becomes broader and less cooperative in the presence of glucocerebroside. The enthalpy change of the main transition decreases with increasing the glucocerebroside content. However, this decrease is not linear with the glucocerebroside/phospholipid mole ratio. Glucocerebroside itself does not show a separate transition in the temperature range of these studies (10--75 degree C). The origin of these effects and their dependence on the glucocerebroside content suggest that the in-plane distribution of glucocerebroside molecules is affected by the physical state of the lipid bilayer and by the glucocerebroside/phospholipid mole ratio.

Formation of lysosulfatide, 3',6'-anhydropsychosine, ceramide, and sphingosine by saponification of cerebroside sulfate. Effect of the sulfate group on the hydrolysis

Saponification of cerebroside sulfate (sulfatide) by refluxing with 1 N KOH in 90% n-butanol for 1 h yielded ceramide, sphingosine, lysosulfatide (psychosine-3'-sulfate ester) and a hitherto unknown compound. The latter compound was identified as 3,6-anhydrogalactosyl sphingosine (3',6'-anhydropsychosine) from its mass spectrum. The structure of lysosulfatide was confirmed by reacylating it to sulfatide by condensing it with lignoceroyl chloride. The resulting sulfatide, which was chromatographically identical to control sulfatides, was not oxidized by periodate. The sulfatide was also permethylated and methanolyzed. The sugar moiety obtained was identified as methyl 2,4,6-tri-O-methylgalactoside by gas-liquid chromatography and thin-layer chromatography. The presence of the sulfate group in lysosulfatide was further confirmed by IR spectroscopy and the presence of radioactivity when it was prepared from [35S]sulfatide. The effect of the sulfate group on cleavage of the galactoside linkage and on the formation of the 3,6-anhydro derivative is discussed.

Influence of reduced cholesterol synthesis on the activity of cerebroside sulfotransferase in cultured glioblastoma cells treated with estradiol

Cultured glioblastoma cells were inoculated with estradiol in concentrations of 0.5--10 microliter/ml medium in order to check the effect of this hormone on the activity of cerebroside sulfotransferase, an enzyme whose activity is strongly related to myelination. Thereby we could show that the cerebroside-sulfotransferase activity increases to a value of 200% of normal. Concomitant to this effect, the cholesterol content of the membrane bearing cerebroside sulfotransferase activity decreases to 60% of normal. The effect is fully reversible: after 48 h, cholesterol synthesis as well as cerebroside sulfotransferase activity reach normal values again. We suggest that cerebroside sulfotransferase activity is modulated by the changing cholesterol/phospholipid ratio in the cells during the inoculation period.

A cellular approach to neurological disease

This presentation is necessarily an overview of the work in our laboratories. We have chosen to study oligodendroglia and myelin first, because we have specific markers we can use, and we can focus on specific disease entities. However, the same strategy can be applied to neurons and neuronal diseases. Despite major advances in the neurosciences, many questions remain unanswered. In general there has been a predictable sequence in our progress in understanding the nature of neurological disorders. Early studies focused on a clinical description of the disease. Next the pathology was described, and attempts were made to correlate these findings with the clinical symptoms. Now that we are able to isolate some of the cells involved in specific diseases (see Table I) we can begin to investigate the normal metabolism of these cells, study their components, and follow any changes that take place under different pathological conditions. Thus, we have shown that it is possible to study and perphaps eventually provide therapy for certain disorders, such as multiple sclerosis, without knowning that delineation of events in the normal cell is an essential step in unraveling the mysteries of neurological disease.

Brain reaggregate cultures: biochemical evidence for myelin membrane synthesis

Myelin membrane synthesis was studied using mechanically dissociated fetal rodent CNS which formed spherical reaggregates while being maintained in rotating culture flasks. These reaggregate cultures exhibited myelinogenesis in vitro after precisely the same period of time needed for myelin synthesis to commence in vivo. The myelin membrane related enzymes, 2', 3' cyclic nucleotide phosphohydrolase (CNP) and cerebroside sulfotransferase (CST), appear similar in their specific activities and follow the same developmental patterns that these enzymes exhibit in vivo. In addition, phosphorylation of myelin basic protein occurs by the third week in vitro which agrees with previously published in vivo studies. These experiments indicate that this nerve-cell culture system may be a appropriate model for studying the biological regulation of myelinogenesis as well as a variety of other nervous-system functions.

Human antithrombin III. Carbohydrate components and associated glycolipid

Human antithrombin III was found to contain covalently linked N-acetylglucosamine, mannose, galactose, and sialic acid in a molar ratio of approximately 1:1:0.6:1. Sialic acid was released upon treatment with neuraminidase. The modified glycoprotein retained the capability to inhibit thrombin and to bind with heparin. Antithrombin III isolated by different procedures was also found to contain glucose in an approximately equimolar ratio with N-acetylglucosamine. Th" glucose-containing component was extractable with lipid solvents and shown to be beta-glucosylceramide. This glycolipid is tightly complexed with antithrombin III and could not be separated by fractional precipitations or ion exchange gels. Although it remains to be established whether the inhibitory actions of antithrombin III are affected by glucosylceramide, the relative amounts which are bound suggest that antithrombin III may be a significant carrier of the glycolipid.

Studies on the function of the activator of sulphatase A

The activator of sulphatase A is necessary for the enzymic degradation of sulphatides to cerebrosides at ionic concentrations in the physiological range (1). Activation is probably due to the reversible formation of a one-to-one complex between activator and sulphatides (1,2). Formation of this complex is partly inhibited by cerebrosides due to competitive binding (2), as well as by phospholipids (e.g. lecithin or phosphatidylserine). Inhibition of the complex formation between activator and sulphatides by cerebrosides and phosphatidyl-serine depends on the concentration of the lipids and is of the same order of magnitude as the inhibition (by these lipids) of the enzymic degradation of sulphatides in the presence of activator (1). Moreover the degradation rate of sulphatides increases with the concentration of activator-sulphatide complex in the reaction mixture (1) indicating that the activator-sulphatide complex is the substrate for the enzyme in the degradation of sulphatides by sulphatase A.

The dispersion of cholesterol with phospholipids and glycolipids

Of the polar lipids studied (phospholipids and glycolipids), only phosphatidylcholine and sphingomyelin can disperse in water with up to 2 mol cholesterol/mol polar lipid. However, mixtures of phosphatidylethanolamine with small amounts of phosphatidylcholine and mixed lipids from mitochondria and myelin will also form sterol-rich dispersions. Steroids in which the 3beta-OH group is replaced by an oxo function do not form such steroid-rich dispersions. Electron microscopy and optical rotatory dispersion (ORD) show that sterols disperse with cerebrosides and gangliosides to form cylindrical structures with the regions around C atoms 3 and 7 of the sterol in less polar environments than those they occupy in phospholipid liposomes. It is proposed that choline-containing phospholipids facilitate entry of sterol molecules into the outer leaflet of cell surface membranes but that the phospholipid composition itself will not give rise to an asymmetric distribution of sterol in membranes with a high cholesterol content.

Interactions of C-reactive protein and complement with liposomes

Interactions between C-reactive protein (CRP) and liposomal model membranes containing phosphatidylcholine were investigated. These interactions, in the presence of human serum, resulted in consumption of each of the components of the classical complement pathway (C1-C9) and also resulted in complement-dependent damage and release of trapped glucose from certain types of liposomes. CRP-initiated lysis of liposomes was strongly dependent upon membrane lipid composition. Optimal activity occurred with positively charged liposomes containing galactosylceramide (galactocerebroside); positively charged liposomes lacking galactocerebroside released much less glucose, while negatively charged liposomes, either with or without galactocerebroside, did not release glucose at all. Glucose release was inhibited by free phosphocholine. Lesser, but significant, "background" glucose release independent of the presence of CRP also was observed with positively charged liposomes containing galactocerebroside, and this was associated with marked preferential consumption of the later-acting complement components (C3-C9). C2-deficient human serum failed to support CRP-dependent glucose release, but glucose release was observed upon reconstitution of the serum with C2. Guinea pig complement also did not support CRP-mediated glucose release, but upon addition of human C1q substantial glucose release was observed. We conclude that (i) CRP can sensitize appropriate liposomes for complement-dependent damage via the primary complement pathway starting at the level of C1q; (ii) of those studied, liposomes that are most susceptible to membrane damage contain phosphatidylcholine, have a positive charge, and contain a ceramide glycolipid; and (iii) such liposomes also are sensitive, although to a much lesser degree, to complement-dependent lysis initiated in the absence of CRP and involving consumption of terminal in excess of early acting complement components.

Age-dependent modulation of 3'-phosphoadenosine-5'-phosphosulfate-galactosylceramide sulfotransferase by lipids extracted from the microsomal membranes and artificial lipid mixtures

The 3'-phosphoadenosine-5'-phosphosulfate-galactosylceramide-sulfotransferase (cerebroside sulfotransferase) is microsomal enzyme, which shows a definite developmental activity pattern. This report gives evidence that the enzyme activity of partially delipidated microsomes is modulated by the cholesterol:phospholipid ratio of the extracted microsomal lipids in an age-dependent manner. These findings suggest that in vivo the enzyme activity is modulated by the lipid surrounding.

Solubilization and partial characterization of UDP-N-acetylgalactosamine: globoside alpha-N-acetylgalactosaminyltransferase from dog spleen microsomes

UDP-N-acetylgalactosamine:globoside alpha-N-acetylgalactosaminyltransferase (EC 2.4.1.-) synthesizing Forssman hapten was solubilized from dog spleen microsomes by a combination of Triton X-100 treatment and sonication. The solubilized enzyme was partially purified by calcium phosphate gel, ammonium sulfate fractionation and then DEAE-cellulose column chromatography. The enzymatic activity of the purified preparation was stimulated by exogenously added phosphatidylserine, as found in the particulate enzyme. When the properties of the purified enzyme were examined in the presence of exogenous phosphatidylserine, the enzyme had an absolute requirement for Mn2+; this was not substituted by Ca2+ or Mg2+. Apparent Km values for UDP-N-acetylgalactosamine and globoside were 1-10(-5) and 5-10(-4) M, respectively. It had a pH optimum of 6.55 regardless of the presence or absence of exogenous lipids. Since the partially purified enzyme was completely free of uridine diphosphatase which was found in the particulate preparaton, the effect of UDP on the transferase activity could be studied. Thus, UDP inhibited 85% of the activity at a concentration of 1.5 mM. p-Cholormercuribenzoate inhibited over 90% of the activity at 2 mM, indicating the transferase to be SH-enzyme.

Purified human liver acid beta-D-galactosidases possessing activity towards G(M1)-ganglioside and lactosylceramide

Our studies with purified human liver acid beta-D-galactosidases (EC 3.2.1.23) indicate that 4-methylumbelliferyl beta-D-galactosidase and G(M1)-ganglioside beta-D-galactosidase activities are identical with lactosylceramidase II activity. Evidence for this includes co-purification of all enzyme activities by affinity chromatography to yield a single band on polyacrylamide-gel electrophoresis and coincident elution from Sepharose 6B of all three enzyme activities.

Micelles of cerebroside sulphate

The critical micelle concentration of cerebroside sulphate in water is 0-01 mM: it increases with increasing concentrations of buffer to 0-07 mM in 0-1 M sodium acetate and formate buffers, pH 5-6 and 4-5 respectively. The partial specific volume of the micelles is about 0-94. The behaviour of the micelles in the ultracentrifuge and on Sephadex G-200 shows them to be grossly heterogeneous with respect to size. In 0-1 M buffer s20,w is about 26 S; in water or 0-01 M buffer smaller micelles with an s20,w of about 6 S are also present. In 0-01 M formate, pH 4-5, the smallest species detectable by equilibrium ultracentrifugation had a micellar weight of about 180,000 corresponding to an aggregation number of about 180. Much larger aggregates were also present. It is suggested that the smallest micelles are the substrate for sulphatase A when this is acting as a cerebroside sulphatase in buffers of low ionic strength.