A STUDY OF LIPID COMPONENTS IN BRAIN OF THE 'JIMPY' MOUSE, A MUTANT WITH MYELIN DEFICIENCY

(1) Brain composition and developmental changes were investigated in a mutant (‘Jimpy’) mouse characterized by a severe myelin deficiency. (2) Significantly lower cholesterol, phospholipid and galactolipid values were observed, and the accumulation of these lipids during the myelination period was markedly reduced or absent. (3) The most remarkable feature of ‘Jimpy’ brain was a very small galactolipid content. In 29-day-old mutants the concentration of galactolipids was 0-18 μ moles/g wet wt., representing a 46-fold decrease when compared to values determined in normal mice. (4) There was no such striking change in the distribution of different phospholipids. However, lowered relative amounts of some phospholipids, e.g. ethanolamine plasmalogen, sphingomyelin and phosphatidylserine, were observed in ‘Jimpy’ brain. (5) Protein content was also lower in mutant brains and showed an absolute decrease after 23 days of life. (6) These data support the statement that the process of myelination is disturbed at an early stage, resulting in a deficiency of mature myelin sheaths and leading probably to the breakdown of primitive myelin structures.     

THE DISTRIBUTION AND BIOSYNTHESIS OF THE MYELIN -GALACTOLIPIDS IN THE SUBCELLULAR FRACTIONS OF BRAINS OF QUAKING AND NORMAL MICE DURING DEVELOPMENT

Abstract— The biosynthesis and accumulation of monogalactosyl diglyceride, galacto-cerebrosides and sulfatides were studied in the brain of quaking mouse during myelination. The specific activity of monogalactosyl diglyceride synthesis of the mutant mouse was reduced to 50% of the control of the same age, comparable to the reduction in the biosynthesis of galactosylcerebrosides and sulfatides. The three galactolipids were largely associated with the myelin and microsomal fractions in the normal and quaking mice at the ages studied. Although the concentrations of microsomal galactolipids (expressed as nmol/g wet wt of brain) were lower in quaking mice than in the controls at all ages, the percentage of total brain monogalactosyl diglyceride recovered in the microsomes of the mutant mouse was always larger than in the microsomes of the controls. Between 16 and 41 days, the monogalactosyl diglyceride content of the control myelin increased 10-fold, whereas the concentrations in the mutant increased only 2-fold. In normal animals, the percentage of total myelin galactolipids in the 'small myelin' decreased over the age of 1841 days with concomitant increase in the 'large myelin'. In contrast, in the mutant, large percentages of these compounds remained associated with the small myelin even at late periods of myelin development. These findings indicate that the slow rate of deposition of myelin in the brain of quaking mouse may be due to a defective transport mechanism of the galactolipids from the site of synthesis (microsomes) to the site of deposition (myelin), or to a defect in the mechanism of final myelin assembly, rather than to a lipid-specific genetic error.     

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.     

COMPOSITION OF CEREBRAL LIPIDS IN MURINE LEUCODYSTROPHY: THE QUAKING MUTANT

The composition of sphingolipids and phospholipids of mouse brain during myelination was determined in the Quaking mutant, which manifests a genetic disorder of myelin formation, and in littermate controls. The biochemical changes during myelination in the brains of the controls corresponded quantitatively with previous findings in a different strain of mice. The Quaking mutant exhibited concentrations of sphingolipids and phospholipids in brain which were comparable to those of controls in the early stage of myelination but the tissue content failed to increase with maturation. The greatest differences occurred in the cerebrosides which at 65 days of postnatal age were only 10 per cent of control levels. During development the pattern of cerebral levels of sphingomyelin, plasmalogen and total phospholipid in the mutants tended to resemble that of the cerebrosides. The defect in the Quaking mutant is compatible with a failure in maturation of myelin. These findings have been compared with those in the Jimpy mutant, a different genetic disorder of myelin in the mouse previously studied in a similar fashion. The Jimpy mutant is characterized by a quantitatively more pronounced deficiency of myelin lipids and a decline in cerebrosides during brain development.     

Incorporation of [3H]thymidine into DNA and of [35S]sulfate into sulfatides of oligodendroglial cells during development: Effect of malnutrition

Incorporation of [³H]thymidine into DNA and of [³⁵S]sulfate into sulfatides of oligodendroglial cells isolated from brain slices incubated with the radioactive precursor was studied in normal and malnourished rats at different ages. The pattern and the values of incorporation of [³H]thymidine into DNA were similar in both groups of animals. The maximum value of incorporation was observed at 7 days of age decreasing rapidly thereafter and leveling off between 18–21 days. In both groups of animals labeling of sulfatides attained a maximum at 18 days of age, showing similar values of incorporation up to that age. However, at 21 days of age; the values corresponding to malnourished rats were found to be 40% lower in comparison to controls. The results suggest that (a) proliferation of oligodendroglial cells stops at similar ages in normal and malnourished rats, (b) expression of sulfatide synthesis by oligodendroglial cells is similar in both groups of animals up to 18 days, and (c) the starved rats seem to be unable to maintain normal synthesis of these galactolipids throughout the entire period of active myelinogenesis.     

Effects of Altered Thyroid States on Myelinogenesis

Abstract: Myelinogenesis was studied in controls and in rats treated since birth with Methimazole (hypothyroid) or thyroxine (hyperthyroid). The amount of myelin in forebrain and its protein composition were determined between 13 and 40 days of age, the period of most rapid myelin accumulation. Hypothyroid rats had reduced body and brain weights relative to controls and the yield of myelin was reduced on both a per brain and a per milligram brain protein basis. Developmental changes in the protein composition of isolated myelin followed the pattern of control animals (the percentage of total myelin protein present as proteolipid protein, large basic protein, and small basic protein increased, as did the ratio of proteolipid/large basic protein) but were delayed temporally by 1–2 days. Hyperthyroid rats also had reduced body and brain weights. At 13 days myelin accumulation was greater than that of controls, corresponding to an earlier initiation of myelination. At later ages myelin yield was reduced on a per brain basis but not on a per milligram brain protein basis. The developmental pattern of myelin protein composition was accelerated temporally by 1–2 days. Myelination in optic nerve, assayed by proteolipid protein content, also was slightly delayed in hypothyroid animals and somewhat accelerated in hyperthyroid animals. The relative synthesis of myelin proteins (determined as incorporation of intracranially injected [³H]glycine into myelin protein relative to incorporation into whole brain protein), as well as distribution of radioactivity among individual myelin proteins, was determined. The results supported the conclusion of the myelin protein accumulation study; hypothyroidism retards the developmental program for myelinogenesis, whereas in the hyperthyroid state myelin synthesis is initiated earlier but is also terminated earlier.     

THE METABOLISM OF PALMITIC ACID IN THE PHOSPHOLIPIDS, NEUTRAL GLYCERIDES AND GALACTOLIPIDS OF MOUSE BRAIN

Abstract— Following intracerebral injection, [¹⁴C]palmitic acid was rapidly incorporated into a variety of brain lipids. After 12 hr, 78 per cent of the lipid radioactivity was in phospholipids, 15 per cent was in triacylglycerols, 1 per cent each was in free fatty acids and galactolipids, and the remainder was in other neutral glycerides. Over 65 per cent of the phospholipid radioactivity was found in the choline phosphoglycerides but this proportion decreased substantially with time. At later times, increasing portions of the radioactivity were present in the monounsaturated acyl groups and the alkenyl groups but no radioactivity was detected in cholesterol or polyunsaturated acyl groups. These results indicate that most of the extensive recycling of radioactivity took place without oxidative degradation of the palmitoyl groups. The relative rates of incorporation of radioactivity were compared at 12 hr after injection. The specific radioactivities of the serine, ethanolamine, and choline phosphoglycerides had ratios of 6:3:2 based on the palmitoyl group content and 1:2:4 based on their phosphorus content. The specific radioactivities of galactolipids with O -acyl groups were higher than the specific radioactivitiesof cerebrosides or cerebroside sulphates. A new solvent mixture for thin-layer chromatography of brain galactolipids was described (chloroform-acetone-methanol-water, 60:20:20:1, by vol.).     

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.     

CHARACTERIZATION OF THE FRACTION OBTAINED FROM THE CNS OF JIMPY MICE BY A PROCEDURE FOR MYELIN ISOLATION

Abstract— A subcellular fraction (called the 0·85-fraction) was isolated from the brains of Jimpy mice by a procedure for obtaining myelin of high purity from immature normal brains. The yield of this fraction obtained from 17-day-old Jimpy mice was only 5 per cent of that from age matched controls. In the electron microscope, the O·85-fractions obtained from 9- and 17-day-old control mice showed many multilayered whorls of myelin, whereas the corresponding fraction from the Jimpy mice was free of multilayered structures which could be recognized as myelin. Basic proteins, proteolipid protein and galactocerebrosides could not be detected in the 0·85-fraction from Jimpy mice although they were major components of the 0·85-fractions from both 9- and 17-day-old control mice. The specific activity of 2',3'-cyclic nucleotide 3'- phosphohydrolase in the Jimpy 0·85-fraction was only 15 per cent of the value for controls. These results can be explained either by the 0·85-fraction from Jimpy brain being a very abnormal 'myelin' or by its being primarily non-myelin contaminants. Little or none of the major glycoprotein found in normal myelin fractions was found in the 0·85-fraction from Jimpy brains. This finding is strong evidence indicating that the glycoprotein is closely associated with normal myelin in situ.     

INFLUENCE OF LIPIDS ON THE ACTIVITY OF CEREBROSIDE-SULPHOTRANSFERASE IN MOUSE BRAIN: A COMPARATIVE STUDY OF JIMPY AND NORMAL MOUSE BRAINS 1

Abstract— The effect of lipids other than the substrate cerebroside on the activity of cerebroside-sulphotransferase (CST) in Jimpy and normal mouse brain was investigated. The enzyme activity of an acetone-treated microsomal preparation can be stimulated in the presence of the extracted lipids either with or without addition of exogenous cerebroside as a substrate. The CST activity in the Jimpy mutant compared to that in normal animals differs from 18% in homogenate to approx 80% in solubilized or acetone-extracted microsomes. An addition of total lipid from normal mouse brain to microsomal preparations from which lipid has been removed by acetone results in a stimulation of Jimpy CST activity up to a value of 80% of normal mouse brain microsomes. Both Jimpy and normal mouse brain CST can be also stimulated by the addition of single lipid components such as cholesterol and lecithin by 50% in normal and 100% in Jimpy brain microsomes. These findings lead to the hypothesis that there is a lipid requirement for CST activity other than the substrate cerebroside.     

FA2H-dependent fatty acid 2-hydroxylation in postnatal mouse brain

2-Hydroxy fatty acids are relatively minor species of membrane lipids found almost exclusively as N-acyl chains of sphingolipids. In mammals, 2-hydroxy sphingolipids are uniquely abundant in myelin galactosylceramide and sulfatide. Despite the well-documented abundance of 2-hydroxy galactolipids in the nervous system, the enzymatic process of the 2-hydroxylation is not fully understood. To fill this gap, we have identified a human fatty acid 2-hydroxylase gene (FA2H) that is highly expressed in brain. In this report, we test the hypothesis that FA2H is the major fatty acid 2-hydroxylase in mouse brain and that free 2-hydroxy fatty acids are formed as precursors of myelin 2-hydroxy galactolipids. The fatty acid compositions of galactolipids in neonatal mouse brain gradually changed during the course of myelination. The relative ratio of 2-hydroxy versus nonhydroxy galactolipids was very low at 2 days of age ( approximately 8% of total galactolipids) and increased 6- to 8-fold by 30 days of age. During this period, free 2-hydroxy fatty acid levels in mouse brain increased 5- to 9-fold, and their composition was reflected in the fatty acids in galactolipids, consistent with a precursor-product relationship. The changes in free 2-hydroxy fatty acid levels coincided with fatty acid 2-hydroxylase activity and with the upregulation of FA2H expression. Furthermore, mouse brain fatty acid 2-hydroxylase activity was inhibited by anti-FA2H antibodies. Together, these data provide evidence that FA2H is the major fatty acid 2-hydroxylase in brain and that 2-hydroxylation of free fatty acids is the first step in the synthesis of 2-hydroxy galactolipids.     

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.     

THE FATTY ACID COMPOSITION OF PHOSPHOLIPIDS AND GLYCOLIPIDS IN JIMPY MOUSE BRAIN

Abstract— Phospholipids and sphingolipids from brains of normal and Jimpy mice were isolated in a pure form by thin-layer chromatographic procedures. The fatty acid composition of the major phospholipids, i.e. ethanolamine glycerophospholipids, serine glycerophospholipids, choline glycerophospholipids and inositol glycerophospholipids, as well as sphingomyelin, cerebrosides and sulphatides was determined by gas-liquid chromatography. A specific fatty acid pattern for each of the four glycerophospholipids was found. The fatty acid composition of inositol glycerophospholipid, which has not previously been studied in mouse brain, was characterized by a high concentration of arachidonic acid. After 16 days of age, fatty acid analysis showed definite differences between the phospholipids from normal and mutant brains. A small increase of polyunsaturated fatty acids in glycerophospholipids of ethanolamine, serine and choline from the Jimpy central nervous system was found, which has been explained by the myelin deficiency. Sphingomyelin, cerebrosides and sulphatide analyses showed a wide distribution of saturated and mono-unsaturated fatty acids in both normal and mutant mice. A reduction in the amount of long-chain fatty acids was demonstrated in mutant brain sphingolipids; in sulphatides and cerebrosides, the amount of non-hydroxy fatty acids was reduced to a greater extent than in sphingomyelin. The distribution of fatty acids in sphingolipids from the myelin and microsomal fractions was also investigated in both types of mice. Cerebrosides were characterized by a high content of long-chain fatty acids in myelin as well as in microsomes. Sulphatides and sphingomyelin, on the other hand, showed a higher content of medium-chain fatty acids in microsomes than in myelin. In the mutant brain, the amount of long-chain fatty acids was reduced in both subcellular fractions. The deviation from normal in the pattern of fatty acid distribution in Jimpy brain is discussed in relation to the current concepts of glycolipid biosynthesis.     

Fatty acid activation in the brains of neurologically mutant mice

1. Palmitoyl-CoA synthetase activity was assayed in subfractions of control and Quaking, Jimpy, Shiverer and Trembler mouse brain. 2. Mouse brain palmitoyl-CoA synthetase activity is not altered during myelination. 3. Mouse brain enzyme activity (homogenate 1.5 +/- 0.3 nmol palmitoyl carnitine/min/per mg protein crude mitochondria 0.6 +/- 0.1 nmol/min/per mg protein and microsomes 1.9 +/- 0.3 nmol/min/per mg protein) does not differ markedly from rat and rabbit brain activity. 4. The lesions of the above mutants which affect myelination and lipid synthesis do not include the enzyme palmitoyl-CoA synthetase.     

Studies on myelin basic protein-specific protein methylase I in various dysmyelinating mutant mice

Jimpy mice are dysmyelinating mutants characterized by producing near normal levels of myelin basic protein (MBP) in the brain but failing to incorporate these proteins into the myelin sheath. In this study, the activity of MBP-specific protein-arginine N-methyltransferase (protein methylase I) was studied in the brains of normal and jimpy mice of different ages. The enzyme activity varied little with age in normal mice but in 18 and 21 days-old homozygous jimpy mice the activity was reduced by 50% and 75% respectively from the level of their normal littermates. Interestingly, however, heterozygous jimpy mice who are phenotypically normal and quaking mice (a similar dysmyelinating mutant) showed unaltered enzyme levels.     

Myelin-Associated Galactolipids in Primary Cultures from Dissociated Fetal Rat Brain: Biosynthesis, Accumulation, and Cell Surface Expression

Galactolipid metabolism was investigated as a function of development in primary cultures initiated from 19-21-day-old dissociated fetal rat brain. Significant amounts of galactocerebrosides, sulfatides, and monogalactosylglycerides were synthesized and accumulated by 8 days in culture. Thereafter the synthetic rates and levels of these galactolipids increased rapidly, reaching maximal values approximately 22-29 days in culture. Galactolipids containing nonhydroxy or 2-hydroxy fatty acid were both synthesized at approximately equal rates. The initial rates of synthesis, investigated at 15, 29, and 50 days in culture, were three- to fivefold higher for galactocerebrosides than for sulfatides and two- to threefold higher than for monogalactosylglycerides. The total number of cells staining with antisera against galactocerebroside of sulfatide also increased very rapidly between 8 and 22 days in culture, reaching levels of 4-5 million cells per seeded fetal brain. The amount of galactocerebroside or sulfatide per cell stained with the corresponding antiserum increased severalfold from 10 to 27 days in culture and remained high until at least 36 days in culture (the latest time point examined). Thus, the temporal expression of galactolipid accumulation in the cell cultures was comparable to that occurring in rat brain, but some important quantitative reductions in the levels of accumulation per cell in culture were noted. In addition, in contrast to normal brain in which galactolipid synthetic rates are reduced after the period of most active myelination, in culture both synthesis and turnover of these galactolipids remained high, suggestive of a partial arrest in myelin maturation.     

ENZYMIC SYNTHESIS OF PSYCHOSINE SULPHATE

—An enzyme which catalyses the synthesis of psychosine sulphate by the transfer of [³⁵S]sulphate from 3′-phosphoadenosine 5′-phosphosulphate to galactosyl-sphingosine has been demonstrated in the brain of the young mouse. The enzyme activity appears to be bound to a microsomal fraction which is spun down with the synaptosomes. The product of the incubation mixture has been characterized as psychosine sulphate by a variety of TLC separations and other chemical procedures. Several parameters (detergent, cations, substrate and 3′-phosphoadenosine 5′-phosphosulphate concentrations, pH and incubation time), affecting the 3′-phosphoadenosine 5′-phosphosulphate-psychosine sulphotrans-ferase activity, have also been investigated. In the normal mouse brain there is a maximum enzyme activity at 17–19 days after birth, which is the period of most rapid myelin formation. In the brains of Jimpy mice, mutants with myelin deficiency, the activity is reduced and reaches a maximum around the 13th day. The lower activity correlates with the small amounts of sulphatides in Jimpy mouse brains. The results are discussed and related to present knowledge of galactolipid biosynthesis.     

Influence of Prenatal Hypoxia on Brain Development: Effects on Body Weight, Brain Weight, DNA, Protein, Acetylcholinesterase, 3-Quinuclidinyl Benzilate Binding, and In Vivo Incorporation of [14C]Lysine into Subcellular Fractions

Abstract: The influence of prenatal hypoxia on subsequent brain development in the young rat was investigated by examining body and brain weight, cerebral cortex wet weight, protein and DNA concentrations, acetylcholinesterase (AChE) activity, 3-quinuclidinyl benzilate (QNB)-binding levels, the relative amounts of protein in various subcellular fractions, and the in vivo incorporation of [¹⁴C]lysine into the protein of homogenate and subcellular fractions. Exposure of pregnant females to a mild hypoxia (9.1% Os, 10 h per day for the 9-11 days preceding birth) resulted in a reduced body weight in the pups at days 1 and 5 after birth; total cortical DNA was reduced but brain weight and protein content were unaffected, leading to a higher protein/DNA ratio in prenatally hypoxic pups. By 10 days of age these differences between prenatally hypoxic and control animals were no longer apparent. There were no differences between prenatally hypoxic and control animals in AChE and QNB binding per milligram cortex protein. The relative amount of synaptic membrane protein from the cerebral cortex was reduced at day 1 in prenatally hypoxic animals and the synaptic membrane fraction showed a higher level of incorporation of [¹⁴C]lysine on days 1, 5, and 10. The developmental profile of [¹⁴C]lysine incorporation showed a peak on day 10 which was higher in prenatally hypoxic rats. By 46 days after birth little difference could be found between prenatally hypoxic and control animals.     

Decreased weight, DNA, RNA and protein content of the brain after neutron irradiation of the 18-day mouse embryo

Pregnant mice were irradiated with 0.5 Gy fission neutrons on the eighteenth day of their gestation. The average litter size at birth was unchanged but mortality increased 5-6 fold in the first 3 days. The irradiated mice were the same weight as control mice at birth but showed a progressively increasing weight deficiency up to at least 36 days as compared to controls. Brain weight was 37, 45 and 25 per cent less in 2-, 3- and 52-week old irradiated animals, respectively, and the ratio of brain weight to body weight was 25, 27 and 13 per cent less. The concentrations of DNA, RNA and protein (mg/g wet tissue) were the same in irradiated and control mice in both brain and liver at all three ages. Total DNA, RNA and protein contents of whole brain after irradiation were 56-75 per cent of the control levels. No definite decrease was observed in liver. Histological study at 6 hours after irradiation showed nuclear pyknosis in the central nervous system from definite to very severe according to the part examined. It is concluded that damage to the central nervous system of the 18-day mouse foetus after neutron irradiation is mainly due to killing and/or inhibition of the differentiation of neuroblasts.     

Myelin Galactolipid Synthesis in Different Strains of Mice

Previous studies have indicated that the brains of DBA/2J (D2) mice have a more heavily myelinated CNS than those of C57BL/6J (B6) at postnatal days 17-21. However, the amount of myelin in the brains of F1 (B6 X D2) hybrids is even higher than in their parental strains. To investigate further factors involved in regulating myelinogenesis in these mice, we have focused on the synthesis of cerebrosides and sulfatides, galactolipids enriched in myelin. Brain slices from 14-, 17-, and 21-day-old D2, B6, and F1 mice were incubated with [3H]galactose and [35S]sulfate. After incubation, microsomes, myelin, and oligodendroglial cells were isolated, and the galactolipids were analyzed. At 21 days of age, the labeling of cerebrosides in F1 mice was higher than in D2 and B6 mice when the results were expressed as microsomal or myelin radioactivity per gram wet weight. At 14 and 17 days of age, the labeling of cerebrosides in F1 animals was similar to that in D2 mice and was considerably higher than that in B6 mice. The labeling of sulfatides in F1 animals was significantly higher than in the B6 parent at all ages studied, whereas it remained higher than that in the D2 parent only at 17 days of age. A similar relationship among the strains was observed when the synthesis of myelin galactolipids was estimated by measuring the in vitro activity of UDP-galactose:ceramide galactosyltransferase and 3'-phosphoadenylyl sulfate:galactosylceramide 3'-sulfotransferase. The results indicate that the increased accumulation of myelin galactolipids previously reported in the F1 mice is partially due to enhanced synthetic activity.