Bile salt activation of cerebroside sulphate sulphohydrolase.

The cholate and taurodeoxycholate activations of cerebroside sulphate sulphohydrolase (cerebroside-3-sulphate 3-sulphohydrolase, EC 3.1.6.8) activity of arylsulphatase A (aryl-sulphate sulphohydrolase, EC 3.1.6.1) were compared. Taurodeoxycholate caused a sharp peak of response at a concentration of 1.25 mg/ml (type-I activation). Cholate also showed type-I activation but, in addition, it evoked a second, higher, response plateau at concentrations between 5 and 10 mg/ml (type-II activation). At the pH of the reaction, cholate is converted largely to the sparingly soluble free aicd, so at the high concentrations associated with type-II activation, copious precipitates were formed. It was found that the precipitated material was essential for the type-II activation. Type-I activation appears to involve bile salt interaction with substrate, while type-II activation appears to involve enzyme interaction with solid-phase cholic acid. the putative mutant arylsulphatase A in an unusual form of metachromatic leukodystrophy hydolysed cerebroside sulphate only in the presence of high levels of cholate. The type-II activation may thus be simulating a physiological desulphation reaction.     

Adhesion between cerebroside bilayers

The structure, hydration properties, and adhesion energy of the membrane glycolipid galactosylceramide (GalCer) were studied by osmotic stress/X-ray diffraction analysis.(1) Fully hydrated GalCer gave a repeat period of 67 A, which decreased less than 2 A with application of applied osmotic pressures as large as 1.6 x 10(9) dyn/cm(2). These results, along with the invariance of GalCer structure obtained by a Fourier analysis of the X-ray data, indicated that there was an extremely narrow fluid space (less than the diameter of a single water molecule) between fully hydrated cerebroside bilayers. Electron density profiles showed that the hydrocarbon chains from apposing GalCer monolayers partially interdigitated in the center of the bilayer. To obtain information on the adhesive properties of GalCer bilayers, we incorporated into the bilayer various mole ratios of the negatively charged lipid dipalmitoylphosphatidylglycerol (DPPG) to provide known electrostatic repulsion between the bilayers. Although 17 and 20 mol % DPPG swelled (disjoined) the GalCer bilayers by an amount predictable from electrostatic double-layer theory, 5, 10, 13, and 15 mol % DPPG did not disjoin the bilayers. By calculating the magnitude of the electrostatic pressure necessary to disjoin the bilayers, we estimated the adhesion energy for GalCer bilayers to be about -1.5 erg/cm(2), a much larger value than that previously measured for phosphatidylcholine bilayers. The observed discontinuous disjoining with increased electrostatic pressure and this relatively large value for adhesion energy indicated the presence of an attractive interaction, in addition to van der Waals attraction, between cerebroside bilayers. Possible attractive interactions are hydrogen bond formation and hydrophobic interactions between the galactose headgroups of apposing GalCer bilayers.     

Total synthesis of alpha-galactosyl cerebroside

A highly convergent synthetic approach was developed to obtain alpha-galactosyl cerebroside O-(alpha-D-galactopyranosyl)-2-hexacosylamino-D-ribo-1,3,4-octa decantriol, which has previously been demonstrated to have immunostimulatory activity. Known 4,6-O-benzylidene galactose was the starting material for both the required alpha-galactosyl and the phytosphingosine building blocks O-(2,3-di-O-benzyl-4,6-O-benzylidene-D-galactopyranosyl) trichloroacetimidate (4) and 2-O-methanesulfonyl-D-arabino-1,2,3,4-octadecantetrol (5). The key step of the synthetic strategy is the highly regio- and stereoselective O-galactosylation of 1,3,4-O-unprotected phytosphingosine acceptor 5 using known 4 as donor. The total synthesis required only 11 synthetic steps starting from galactose.     

Composition of human cerebrospinal fluid cerebroside

A technique was developed to isolate sufficient material for compositional analysis of cerebroside from pooled human cerebrospinal fluid. The carbohydrate moiety was principally galactose. The sphingosine base and fatty acid compositions were found to be similar to that of brain cerebroside. The presence of a contaminant in commercial silica gel which chromatographed like the trimethylsilyl derivative of glucose is described.     

Characterisation of cerebroside 3-sulphate dispersions

Galactosyl ceramide 3-sulphate (cerebroside 3-sulphate) was tritiated using [³H]NaBH₄ with PdCl₂ as catalyst. Quantitative purification of the three components of the product was achieved by chromatography on Florisil. Dispersions, prepared by either low energy sonication or by dilution from organic solvent, were compared by controlled pore glass chromatography, ultra-centrifugation and electron microscopy. Both dispersion techniques were shown to form unilamellar vesicles, the average size of vesicles produced by sonication being far larger than those produced by solvent dilution. The diameter of isolated vesicles produced by solvent dilution was in the range 10–80 nm.     

Induction of cerebroside synthesis in oligodendroglia

Oligodendroglia function to produce myelin membranes which surround axons, enhancing saltatory conduction. Myelin consists of a multitude of condensed membranes which are rich in lipids with the major glycolipids, cerebrosides, being 25% of the total lipid. Thus a fully differentiated oligodendroglial cell that is producing myelin membranes would be actively synthesizing cerebrosides. Our laboratory has prepared and analyzed oligodendroglia from mature bovine brain, from neonatal rat brain, and from actively myelinating rat brain. Our studies suggest that the rat oligodendroglia in our culture systems are less differentiated than bovine cells in that they produce lower levels of cerebrosides. Addition of glucocorticoids, thyroid hormone, or retinoic acid all increased synthesis of cerebrosides in rat oligodendroglia. Ketone bodies were also somewhat stimulatory. Having no effect or causing dedifferentiation of the cells were 5-azacytidine and phorbol esters. Thus induction of cerebroside synthesis in oligodendroglia is complex and may involve many factors.     

The effect of the interdependence of protein and bile salt concentrations on the measurement of cerebroside sulphate sulphatase activity in human leucocyte and fibroblast extracts

The previously observed differences in properties of human leucocyte and fibroblast cerebroside sulphate sulphatase (cerebroside-3-sulphate 3-sulphohydrolase, EC 3.1.6.8) measured in vitro have been found to be due to subtle differences in incubation conditions. Maximum enzyme activity was observed with either crude sodium taurocholate or with pure sodium taurodeoxycholate. The optimum bile salt concentration of the enzyme in leucocyte or fibroblast extracts, but not the pure ox liver enzyme, was critically dependent on protein concentration. At low concentrations of the latter (less than 0.1 mg/ml), maximum activity was observed at taurocholate concentrations less than 0.5 mg/ml; at protein concentrations greater than 0.20 mg/ml substantially more bile acid (more than 1.3 mg/ml) was required to stimulate maximum activity. Addition of Triton X-100 or bovine serum albumin to the incubation mixtures increased the optimum taurocholate concentration. The dependence of the bile salt optimum on protein concentration appears to be related to the binding of the lipid substrate to membranous protein present in the tissue extracts. Release of the bound lipid is effected either by increasing the bile salt concentration or by adding Triton X-100. In the presence of excess bile salt human leucocyte, fibroblast and liver cerebroside sulphate sulphatase activity is stimulated by Triton at low protein concentrations; under identical conditions the pure or crude ox-liver enzyme is substatially inhibited. Our data also show that cerebroside sulphate sulphatase activity measured in extracts from leucocytes and fibroblasts, the tissues normally used to effect a diagnosis of metachromatic leucodystrophy, is the result of a complex interaction of bile salt, protein, Triton X-100 and probably the substrate itself. Any slight alteration in any of those factors, without a corresponding change in any or all of the others, can have a marked effect on the measured enzyme activity, and may lead to errors in the diagnosis of metachromatic leucodystrophy.     

Reptile brain cerebrosides and cerebroside sulfates

Studies have been made on the content of cerebrosides and cerebroside sulfates, as well as on their fatty acid composition in the brain of reptiles, subclass Anapsida (tortoises Emys orbicularis and Testudo horsfieldi) and subclass Lepidosauria (lizards Agama caucasica, A. sanguinolenta, Phrynocephalus mystaceus and snake Natrix tesselata). Total content of cerebrosides and cerebroside sulfates is higher in the brain of Lepidosaurians than in that of Anapsids. In the brain of tortoises, the content of cerebroside fraction with hydroxy fatty acids is significantly higher than of the fraction with normal fatty acids, which is also typical of the brain of homoiothermic mammals and birds. In the brain of Lepidosaurians, concentration of hydroxycerebrosides is considerably lower than of cerebrosides with normal fatty acids, which is similar to lower vertebrates -- amphibians and fishes. Low content of hydroxycerebrosides was found in all the Lepidosaurians investigated, irrespectively of their ecological conditions, being therefore dependent on their phylogenetic position. The composition of fatty acids, both normal and hydroxyderivates, as well as that of glycolipids from the brain of Anapsids and Lepidosaurians is essentially similar. However, some interspecific differences were noted in the pattern of fatty acids of cerebrosides and cerebroside sulfates of the brain, which concern the content of saturated and long chain fatty acids.     

The cerebroside sulfate activator from pig kidney: Derivitization,cerebroside sulfate binding,and metabolic correction

Highly purified cerebroside sulfate activator from pig kidneys was characterized by a number of chemical and biological procedures. Methods for chemical modifications were evaluated in an attempt to obtain biologically active derivatives. Iodination, dabsylation, and to a lesser degree reductive methylation provided useful products with good retention of cerebroside sulfate activator activity. Other procedures resulted in largely inactive derivatives or losses in both protein and biological activities. Attempts at renaturation of cerebroside sulfate activator subjected to various denaturing conditions appeared to be successful in many instances, but it was uncertain if the protein structure had actually been disrupted. The binding of cerebroside sulfate by activator was estimated by gel filtration under conditions similar to those of its assay. The formation of a relatively stable 1:1 complex was observed, collaborating results with the human protein. The complex was stable enough to be isolated and shown to be an efficient substrate for arylsulfatase A. The effectiveness of the pig kidney cerebroside sulfate activator for correcting the metabolic defect in activator-deficient human fibroblasts was compared with human materials. The pig kidney protein was taken up more efficiently by the cells and resulted in a better metabolic correction than material from human liver, but was somewhat less effective than a preparation from human urine.     

Preparation of asymmetric,cerebroside sulfate-containing phospholipid vesicles

A procedure is described which inserts asymmetrically cerebroside sulfate (‘sulfatide’) into the outer leaflet of bilayered phospholipid vesicles. Cerebroside sulfate is adsorbed onto a cellulose, filter-paper support and, when incubated with phosphatidylcholine vesicles is transferred to and inserted into the outer leaflet of these vesicles. This transfer occurs at, or above the transition temperature of the phospholipid and follows a similar pattern with small or larger (‘fused’) unilamellar vesicles. The transfer is linear with time for 1–2 h and is maximal after about 6 h, when the sulfatide content reaches about 6 mol% of the total quantity of phospholipid, corresponding to about 10 mol% of the phospholipids present in the outer layer. Initial rates of sulfatide transfer were somewhat increased when the vesicles contained a positively charged lipid (e.g. stearylamine) and decreased when this lipid was negatively charged (e.g. dicetyl phosphate) or hydrophobic (e.g. cholesterol). Divalent ions markedly inhibited sulfatide transfer and monovalent ions did so to a lesser degree. Once incorporated into the outer leaflet of the vesicle, the sulfatide could not be removed by washing with buffer, 1 M NaCl or 1 M urea.     

Ceramide-like synthetic amides that inhibit cerebroside galactosidase

Amides resembling ceramide (fatty acyl sphingosine) were synthesized and tested for their effects on rat brain cerebrosidase (galactosyl ceramide beta-galactosidase). The best inhibitor was N-decanoyl dl-erythro-3-phenyl-2-aminopro-panediol, which exhibited a K(i) of 0.4 mm. A Lineweaver-Burk plot indicated that the amide acted as a noncompetitive inhibitor, presumably by attachment to a site other than the substrate-active site. Preincubation did not affect the degree of inhibition, and inhibition was independent of incubation duration; these observations suggest that the inhibitor does not combine with the enzyme irreversibly. Structural variations produced decreased inhibitory activity: loss of one of the hydroxyl groups, replacement of the aromatic side chain with an aliphatic or substituted phenyl group, or isomeric inversion of the 3-hydroxyl group. It appears that the best activity is obtained with a substance most closely resembling natural ceramide. The cerebrosidases of rat spleen, kidney, and liver are also inhibited by the same amide.