A comparative study of brain and kidney glycolipids in metachromatic leucodystrophy

Sulphatides and cerebrosides from white matter of brains of patients with metachromatic leucodystrophy (MLD) have been isolated and compared in fatty acid composition to those glycolipids found in MLD kidney tissue. A marked difference in glycolipid composition was found between the brain and kidney tissues. The sulphatides accumulated in MLD kidney have the same fatty acid profile as those found in normal kidney tissue and are typical‘kidney sulphatides.’The neutral glycolipids of MLD kidney retain larger amounts of the longer chain acids than do the cerebrosides of MLD brain white matter and thus resemble more closely in fatty acid composition, glycolipids of normal tissue. Structurally, the sulfate group is located at the C-3 position of the galactose molecule in sulphatides from normal and MLD tissue. As in the brain white matter, the sulphatides which accumulate in the kidney tissue of patients with MLD are normal in structure and composition.     

SPHINGOLIPIDS AND PHOSPHOLIPIDS IN MICROSOMES AND MYELIN FROM NORMAL AND PATHOLOGICAL BRAINS

—Myelin and microsomes were separated from human cerebral white matter and cortex respectively using the technique of 15% caesium chloride and their sphingolipid and phospholipid contents estimated. Normal brains as well as cerebral material from cases of metachromatic leucodystrophy, Krabbe's disease and Tay-Sachs’disease were studied. Gangliosides were not present in normal myelin but were found in microsomes and in myelin from the pathological material. The ratio of cerebroside to sulphatide in myelin was 4 to 1 in normal, 1 to 20 in metachromatic and 7 to 1 in Krabbe's disease. The results in the human material are briefly discussed.     

Hereditary demyelinating diseases - the leukodystrophies

Schilder's disease and Greenfield's metachromatic leucodystrophy are hereditary demyelinating diseases, which are probably metabolic and lysosomal, although the responsible enzyme is not yet known for all.     

A histochemical study in Huntington's disease and control cases.

1. Extracellular deposits of cerebrosides and free fatty acids were found in the formaldehyde fixed frozen sections of the frontal lobe in 8 cases of Huntington's disease, in one case of the infantile form of Gaucher's disease, 2 cases of Krabbe's globoid cell leucodystrophy, 2 cases of metachromatic leucodystrophy, one case with multiple sclerosis, 2 cases with cerebral contusion and one case with bacterial meningitis. 2. The cerebroside deposits were present in the white matter as well as in the grey matter. 3. The significance of these findings in relation to their etiology is discussed.     

Comparative activity of arylsulphatases A and B on two synthetic substrates.

Rat liver and human skin fibroblasts arylsulphatase A and B activities on both 4-methylumbelliferyl sulphate and 4-nitrocatechol sulphate were compared. The intracellular distribution of activity differed markedly when 4-methylumbelliferyl sulphate was used from that observed with 4-nitrocatechol sulphate. No discrimination between control and metachromatic leucodystrophy or mucopolysaccharidosis (type VI) could be achieved when 4-methylumbelliferyl sulphate was used as substrate. These results contrast sharply with those obtained with 4-nitrocatechol sulphate and cast doubt on the validity of 4-methylumbelliferyl sulphate as substrate for the determination of arylsulphatase A and B activities.     

FATTY ACID COMPOSITION OF CEREBROSIDES, SULPHATIDES AND CERAMIDES IN MURINE LEUCODYSTROPHY: THE QUAKING MUTANT

Abstract— The fatty acid composition of cerebrosides, sulphatides and ceramides has been determined at 20 days postpartum in the brains of Quaking mutant mice and of littermate controls. There was a significant deficit in the proportion of long-chain fatty acids (C₂₂-C₂₄) affecting both normal and a-hydroxy fatty acids of the cerebrosides. The proportion of normal but not the a-hydroxy long-chain fatty acids of the sulphatides was also decreased. Striking and disproportionate deficits of the C_24:1 and C_{24 h:1} fatty acids of cerebrosides, sulphatides and ceramides characterized the brain of the Quaking mutant, and an increased proportion of C_{23 h:O} fatty acid was found in the cerebrosides and sulphatides of the brain of this mutant. We compared these data with findings on the Jimpy mutant which has been examined by the same techniques. The deficiency of long-chain fatty acids which was found in the cerebrosides and sulphatides of both mutants was less extensive but more selective in the Quaking mutant.     

CHOLESTEROL ESTER METABOLIZING ENZYMES IN HUMAN BRAIN: PROPERTIES, SUBCELLULAR DISTRIBUTION AND RELATIVE LEVELS IN VARIOUS DISEASED CONDITIONS

We have in the present study examined the properties and subcellular distribution of cholesterol ester metabolizing enzymes in human brain, and compared the levels of these enzymes in brains from patients with phenylketonuria (PKU), metachromatic leucodystrophy (MLD), and Down's Syndrome (DS). Cholesterol esterification was optimal at pH 5.6, did not require ATP or CoA as cofactors and was inhibited by detergents (TWEEN-20 and Triton X-100) and bile acids (sodium taurocholate and sodium deoxycholate). The specific activity of the cholesterol esterifying enzyme was highest in the mitochondrial fraction. Cholesterol esterifying activity in brains from PKU, MLD, and DS patients was not significantly different. Cholesterol ester hydrolase activity in human brain peaked at two different pHs (4.5 and 6.5). The activity was optimal when the substrate was dispersed in Triton X-100 and sonicated. The specific activity of the pH 4.5 hydrolase was highest in the mitochondrial fraction, while that of the pH 6.5 hydrolase was highest in myelin. The sulfhydryl group reagent parachloromercuribenzoate (PCMB) inhibited the activity of the hydrolase(s) but diisopropylfluorophosphate (DFP), a typical serine reagent, had no effect on hydrolase(s) activity. Addition of either phosphatidyl serine or phosphatidyl inositol significantly enhanced the hydrolase activity at both pHs. The level of cholesterol ester hydrolase(s) in PKU brains was lower than in the brains from DS patients, and the level of these enzymes in the brains from two patients with metachromatic leucodystrophy was lower than in the brains from PKU patients. It is concluded that the properties and subcellular distribution of cholesterol esterifying enzyme in human brain is similar to that in rat brain (Ero & Suzuki , 1971) but that the hydrolases in human brain differ from that in rat brain in several respects, and that the low levels of hydrolase(s) activity in MLD and PKU brain may be related to reduced myelin content of those brains.     

he sulphatase of ox liver XVII. Sulphatase A as a glycoprotein

The glycoprotein nature of sulphatase A has been confirmed. The monomer of sulphatase A (mol. wt 107 000) contains eight molecules of glactose, 14 of mannose, 18 of glucosamine and eight of sialic acid together with traces of focuse and glucose. The latter may be contaminant. Treatment of sulphatase A with neuraminidase quantitatively removes the sialic acid showing that this must be in the terminal position of the carbohydrate. The desialylated enzyme retains the properties of native sulphatase A apart from a slight change in charge and it is quite distinct from sulphatase B. The desialylated enzyme still hydrolyses cerebroside sulphate.The implications of these findings in the biochenmistry of metachromatic leucodystrophy are considered.     

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.     

Biochemical,psychometric, and neuropsychological studies in heterozygotes for various lipidoses

Summary A sample of 38 clinically unaffected carriers for various lipidoses and their noncarrier relatives was studied with biochemical, psychological, and neuropsychological tests under blind conditions. The largest group of carriers was that for metachromatic leucodystrophy (MLD). The mean activity of arylsulphatase A or cerebroside sulphatase in the obligate carriers was 25%–30% of the control values, some heterozygotes showing little more activity than MLD patients. It was found that compared with the controls all heterozygotes (both obligate and facultative) differ unfavourably in some personality traits and in WISA subtests, including capacity for spatial cognition. These differences are especially obvious in a group of seven MLD carriers from the same family.With respect to reaction times, performance was significantly slower in MLD carriers, and particularly in those with enzyme activity lower than 30% of the control values.     

A superfamily of metalloenzymes unifies phosphopentomutase and cofactor-independent phosphoglycerate mutase with alkaline phosphatases and sulfatases

Sequence analysis of the probable archaeal phosphoglycerate mutase resulted in the identification of a superfamily of metalloenzymes with similar metal-binding sites and predicted conserved structural fold. This superfamily unites alkaline phosphatase, N-acetylgalactosamine-4-sulfatase, and cerebroside sulfatase, enzymes with known three-dimensional structures, with phosphopentomutase, 2,3-bisphosphoglycerate-independent phosphoglycerate mutase, phosphoglycerol transferase, phosphonate monoesterase, streptomycin-6-phosphate phosphatase, alkaline phosphodiesterase/nucleotide pyrophosphatase PC-1, and several closely related sulfatases. In addition to the metal-binding motifs, all these enzymes contain a set of conserved amino acid residues that are likely to be required for the enzymatic activity. Mutational changes in the vicinity of these residues in several sulfatases cause mucopolysaccharidosis (Hunter, Maroteaux-Lamy, Morquio, and Sanfilippo syndromes) and metachromatic leucodystrophy.     

The activator of cerebroside sulphatase. Binding studies with enzyme and substrate demonstrating the detergent function of the activator protein.

1. Sulphatase A (cerebroside sulphatase) (EC 3.1.6.1.) and a 12-fold excess of its physiological activator protein were chromatographed together on Sephadex G-75. The elution buffer was the same as that used in the enzymic degradation of sulphatides. The two proteins were eluted in different peaks indicating that no stable complex formed. 2. Activator protein was incubated with sulphatides under conditions used favouring the sulphatase activity. Incubation solutions were then examined by electrophoresis on a polyacrylamide gel gradient. An one-to-one complex between activator and sulphatides was observed. Half maximal binding occurred with 2.5 nmol of sulphatides together with 1 or 2 nmol of activator in 100 micronl. 3. Cerebrosides as the enzymic degradation products of sulphatides, bind also to the activator protein. A ratio of one-to-one could possibly be obtained at high cerebroside concentrations. The binding to cerebrosides is less specific than that to sulphatides. A 7-fold excess of cerebrosides was necessary for half maximal binding. 4. In a mixture of sulphatides and cerebrosides the formation of the complex with the activator protein is partly inhibited. The total amount of bound lipids changed as the composition of the lipid mixture was varied. In a one-to-one mixture of the two lipids 60% of the total bound lipids are sulphatides and 40% are cerebrosides.     

FATTY ACID COMPOSITION OF CEREBROSIDES, SULPHATIDES AND CERAMIDES IN MURINE SUDANOPHILIC LEUCODYSTROPHY: THE JIMPY MUTANT

The fatty acid composition of cerebrosides, sulphatides and ceramides was determined at 15-16 days post partum in the brain of the Jimpy mutant and in littermate controls. There was a marked deficit in the long chain fatty acids (C₂₂-C₂₄) of cerebrosides and sulphatides of Jimpy brain, with the unsubstituted fatty acids affected more than the alpha-hydroxy fatty acids. A decrease of long chain normal fatty acids was also found in the ceramides of Jimpy brain. The deficit of long chain fatty acids in these sphingolipids of the Jimpy brain was more severe than that found in the Quaking mutant which has a less extensive disorder of myelin formation.     

Histochemical localization of the soluble arylsulphatase activities in rat brain

Summary The modified method of Goldfischer has been used for the localization of soluble arylsulphatase activities in the rat brain. The highest activity of these enzymes was found in some parts of the drive system and in nervous tracts. The bulk of activity in neurons and glial cells is localized in the lysosomes. Some arylsulphatase activity has been found to be bound to myelin sheaths. We have not been able to ascribe this activity to any defined subcellular structures, by light microscopy.The method of Goldfischer does not permit differentiation of the two soluble arylsulphatases (enzymes: A and B). We suggest however, that these enzymes may have different functions in the brain. Arylsulphatase A (cerebrosidesulphatase) may be primarily connected with the nervous tracts, a hypothesis supported by the character of disorders caused by lack of this enzyme in metachromatic leucodystrophy. Arylsulphatase B, hydrolysing sulphuric esters of catecholamines, may be involved in the function of the drive system.Arylsulphate sulphohydrolase, EC 3. 1.6. 1.     

THE PATTERNS OF ARYLSULPHATASES A AND B IN HUMAN NORMAL AND METACHROMATIC LEUCODYSTROPHY TISSUES AND THEIR RELATIONSHIP TO THE CEREBROSIDE SULPHATASE ACTIVITY

Abstract— The arylsulphatase A and B patterns of human tissues and leucocytes have been established by isoelectric focussing. Assay conditions, which enable an evaluation of these patterns as quantitatively as possible, have been studied. The dependences of the enzyme patterns on the origin of the tissues and on the storage conditions have been determined. The arylsulphatase A obtained by isoelectric focussing exhibits cerebroside sulphatase activity in the presence of detergents. A purified preparation of the arylsulphatase B likewise shows a significant, although low, cerebroside sulphatase activity. In cases of the conventional types of metachromatic leucodystrophy the arylsulphatase A activity is missing, while in an atypical form of this disease ('ML Variant' according to A ustin et al . (1965) the arylsulphatase A, B and C activities are deficient. In both forms, however, residual activities of the deficient enzymes could be detected which showed isoelectric points identical to those of the normal enzymes.
The following nomenclature is proposed: 'Variant B' for the conventional type, in which the arylsulphatase B activity is present, and 'Variant O' for the exceptional cases, in which all arylsulphatase activities are deficient. The significance of the cerebroside sulphatase activity of arylsulphatase B for a possible residual turnover of cerebroside sulphates in the conventional type of the disease is discussed.     

Adsorption of uni and divalent cations to planar bilayer membranes containing sulphatides or phosphatidylserine

It has been postulated that sulphatides may be the K+ binding site of the sodium pump. In order to test this hypothesis we studied the binding of K+ to bilayer membranes containing sulphatides or phosphatidylserine. The adsorption constants of Na+, K+ and Ca2+ to planar bilayers containing these acidic lipids were determined from changes in the electrostatic potential at the membrane surface. Our results indicate that univalent cations adsorb weakly to both lipids and Ca2+ binds more strongly. The sequence of ion binding was Ca2+ greater than Na+ greater than K+. These results indicate that K+ does not bind specifically to sulphatides or phosphatidylserine and rule out the proposal that sulphatides by themselves provide the K+ binding site of the sodium pump.     

BIOSYNTHESIS AND COMPOSITION OF BRAIN GALACTOLIPIDS IN NORMAL AND HYPOTHYROID RATS

Abstract— Newborn rats were rendered hypothyroid by methimazole treatment. Incorporation of [1-¹⁴C]galactose both in vivo and in vitro into brain cerebrosides of hypothyroid rats was significantly lower than in normals. Biosynthesis of sulphatides was affected by hypothyroidism to a smaller extent than cerebrosides. Assay of cerebroside biosynthesis from [1-¹⁴C]galactose or UDP-[1-¹⁴C]galactose by brain preparations revealed that incorporation of the sugar in both cases is affected to the same extent by methimazole treatment, suggesting that the phenomenon is not due to impairment of the nucleotide biosynthesis. A radioactive galactolipid tentatively characterized as glycerogalactolipid was synthesized in vitro and its biosynthesis was reduced to a large extent in the brain preparations from hypothyroid rats. The fatty acid composition of cerebrosides and sulphatides from the brains of hypothyroid rats was found to be different from that of normal rats. The percentage of normal C₂₄ fatty acids was significantly decreased in the methimazole-treated rats. Brain sphingomyelin fatty acids did not differ between normal and hypothyroid rats.     

Sulphatides and pollination in Oenothera missouriensis

Analyses of the sulphatides in the pollen and style of Oenothera missouriensis show that these membranous lipids are comparatively less important in the styles than in the pollen. Incompatible pollination is followed by a large increase in sulphatides, whereas cross-pollination also causes an increase in sulphatide but to a much lesser extent. This mobilization of sulphatides in the membrane is discussed in term of permeability.     

Ceramide galactosyltransferase and cerebroside sulphotransferase in chicken brain cellular fractions and glial and neuronal cells in culture.

Enzymes involved in the synthesis of cerebrosides and sulphatides were assayed in cultured cells of neuronal and glial origin and their activity compared to that found in analogous fractions prepared from chicken brain. High activity was observed for both enzymes in chicken neuronal and glial fractions. However ceramide galactosyltransferase could not be detected in normal glial cells or neuroblastoma cells. A very low activity was found in the glioblastoma cells. Although sulphotransferase was absent from normal glial cells, a notable activity was found in glioblastoma or neuroblastoma cells.     

Lipid content in brain and spinal cord during experimental allergic encephalomyelitis in rats

Abstract— The content of cerebrosides, sulphatides, gangliosides, cholesterol and phospholipids was evaluated in the brain and spinal cord of rats during the acute and recovery stages of experimental allergic encephalomyelitis (EAE). During the acute stage there was a significant decrease of sulphatides and gangliosides in spinal cord; in brain, only sulphatides were diminished. In the recovery stage, cerebrosides and gangliosides were decreased in the brain, whereas the lipid content of the spinal cord was similar to that in control animals. Cholesterol esters were detected in the brain and spinal cord during both periods. The results show that the changes are not the same for brain and spinal cord during the acute and recovery stages and that glycosphingolipids from either white or grey matter seem to be preferentially altered.