Membrane instability induced by purified myelin components. Its possible relevance to experimental allergic encephalomyelitis

The fusogenic properties of purified myelin components in a system employing chicken erythrocytes were studied. Sulphatides, myelin basic protein and the apoprotein of Folch-Lees proteolipid were capable of individually inducing membrane fusion in the presence of Ca²⁺. By contrast, cerebrosides or a mixture of sulphatides and myelin basic protein (molar ratio 19 : 1) did not show such effect. The fusogenic ability of sulphatide was correlated to its behaviour in mixed monolayers with phospholipids at the air-water interface. Mixed films of sulphatides with phosphatidylcholine or sphingomyelin but not with phosphatidylethanolamine showed reductions of molecular packing and surface potential similar to those found for other fusogenic compounds. The effects of myelin components described could be of importance in the membrane instability and vesicular disruption of myelin occurring in demyelinative disorders.     

Neurotransmitter movements in nerve endings. Influence of substances that modify the interfacial potential

Polysialogangliosides, sulphatides, glycerylmonooleate, unsaturated fatty acids, myelin basic protein and sucrose inhibit the Na+-coupled uptake and induce a Ca2+-dependent release of dopamine from nerve endings. Substances chemically related to those referred to above, such as monosialogangliosides, neutral glycosphingolipids, glycerylmonostearate, saturated fatty acids and albumin, do not show these effects. Mixtures of polysialogangliosides or sulphatides with myelin basic protein or albumin inhibit, to different degrees, the effects of the individual components. The decreased uptake induced by sucrose reverted to control levels upon reduction of the concentration of the perturbing agent. The restoration of the uptake was probably mediated by the Na+-pump reconstituting the transmembrane Na+-gradient necessary for the Na+-coupled cotransport of dopamine. It is suggested that the effects of uptake inhibitor or release inducer agents derive from their ability to decrease the surface potential and modify the molecular organization of phospholipid interfaces which can result in changes of the membrane ionic permeability.     

Interaction of soluble and membrane proteins with monolayers of glycosphingolipids.

1. The interactions of four proteins (albumin, myelin basic protein, melittin and glycophorin) with eight neutral or acidic glycosphingolipids, including sulphatides and gangliosides, five zwitterionic or anionic phospholipids and some of their mixtures, were studied in lipid monolayers at the air/145 mM-NaCl interface. 2. In lipid-free interfaces, the surface pressure and surface potential reached by either soluble or integral membrane proteins did not reveal marked differences. 3. All the proteins studied showed interactions with each of the lipids but the maximal interactions were found for basic proteins with acidic glycosphingolipids. 4. Surface-potential measurements indicated that different dipolar organizations at the interface can be adopted by lipid-protein interactions showing the same value for surface free energy. 5. The individual surface properties of either the lipid of protein component are modified as a consequence of the lipid-protein interaction. 6. In mixed-lipid monolayers, the composition of the interface may affect the lipid-protein interactions in a non-proportional manner with respect to the relative amount of the individual lipid components.     

ALTERATION OF MYELIN BIOSYNTHESIS IN SLICES OF RABBIT SPINAL CORD BY ANTISERUM TO MYELIN BASIC PROTEIN AND BY PUROMYCIN 1

Abstract— Slices of rabbit spinal cord were incubated with [³H]tyrosine and [³⁵SO₄] in the presence of either 5% antiserum to myelin basic protein or 0.21 mM-puromycin. The degree of incorporation of the precursors into the basic protein (BP), the proteolipid protein (PLP) and into sulphatides, as a representative lipid, in isolated myelin was investigated. Anti-BP serum inhibited the incorporation of [³H]tyrosine into BP and PLP from 22 to 46% as compared to controls, whereas puromycin nearly completely inhibited incorporation. The incorporation of [³⁵SO₄] into sulphatides was inhibited by anti-BP serum from 20 to 34% and by puromycin from 33 to 65% as compared to controls. These alterations were myelin-specific as shown by the equal or even increased incorporation of the precursors into the homogenates of spinal cord. The results are discussed in relation to the interaction of lipids and proteins in membrane assembly.     

X-ray diffraction and electron microscope study of the interactions of myelin components. The structure of a lamellar phase with a 150 to 180 A repeat distance containing basic proteins and acidic lipids

A variety of phases has been studied: those formed by lipids extracted from myelin, the basic myelin proteins A1 (from the central nervous system) and P1 (from the peripheral nervous system) or other basic proteins. A particularly interesting type of phase was observed which consists of one of the basic proteins of myelin, acidic phospholipids and sulphatides; this phase is lamellar and contains two lipid bilayers in its unit cell. The structure of this phase was determined by the pattern recognition technique and by electron microscope observations of OsO₄-flxed and freeze-etched preparations. It is formed by two different lipid bilayers, one containing mainly the phospholipids with the hydrocarbon chains in a liquid-like conformation and the other containing mainly the sulphatides with at least one fraction of the chains stiff and hexagonally packed. Under the effect of high temperature, or if cholesterol is added, this phase is replaced by other phases which lack the large repeat. The segregation of the lipids and their specific associations with the basic proteins are discussed in relation to the structure of myelin.     

The intrinsic fluorescence of isolated central-nervous-system myelin-sheath preparations.

The intrinsic fluorescence characteristics of tyrosine and tryptophan residues in the proteins of isolated central-nervous-system myelin were investigated to gain information concerning the location of these residues within the intact membrane system. Tryptophan fluorescence from isolated myelin has an emission maximum at 325 nm that appears to arise from at least two different populations of tryptophan residues. Further evidence for heterogeneity of tryptophan location in the membrane is obtained from quenching studies with chloroform and acrylamide. It is speculated that one tryptophan population is hydrophobically situated and may be derived from the proteolipid protein of myelin, whereas the other tryptophan population is located at the membrane surface and may arise from the extrinsic basic protein. A significant tyrosine fluorescence is detected from isolated myelin, indicating that some of these residues are not quenched by structural interactions within the lipid--protein membrane system. Studies with freeze-dried resuspended myelin suggest that the structural arrangement of protein components in the dried rehydrated membrane system differs significantly from that of the freshly isolated myelin membrane.     

Butanol extracts from myelin fragments. VI. Lack of specificity of 5-hydroxytryptamine binding to recombinate fraction with sulphatides and phosphatidylinositol

To clarify the participation of sulphatides and PI for the binding of 5-HT to myelin butanol extracts, binding experiments of ¹⁴C·5-HT to the recombinate fraction of these two acidic lipids were performed. The recombinate fraction was incubated with 5 × 10^?7 M of ¹⁴C·5-HT, and elution profile of ¹⁴C·5-HT, sulphatides and PI was examined by Sephadex LH₂₀ column chromatography. Three components were eluted with CM 4:1 and elution areas of those relatively corresponded to each other. On the other hand, when 3 fold excess volumes of solvents were used ¹⁴C·5-HT was also eluted with CM 4:1 but the clear difference was observed in the elution pattern of sulphatides and PI. In the myelin butanol extracts, we have reported that the 5-HT binding macromolecules present in the myelin extracts would be composed of saturable and non-saturable components, and ACh, DA and tryptamine specifically inhibited the saturable 5-HT binding. Therefore, on the recombinate system of two acidic lipids the specificity of ¹⁴C·5-HT binding was investigated by displacement experiments. The results indicated that only ACh slightly inhibited the ¹⁴C·5-HT binding but 5-HT, DA and tryptamine had no effect. All these observations suggest that other component(s) besides sulphatides and PI may be implicated in the binding of 5-HT to myelin butanol extracts.     

Endogenous cyclic AMP-stimulated phosphorylation of a Wolfgram protein component in rabbit central-nervous-system myelin.

Cyclic AMP-stimulated phosphorylation of membrane proteins in central-nervous-system myelin was investigated, with rabbit brain myelin. Subfractionation of a myelin membrane preparation by sucrose-density-gradient centrifugation produced a rapidly sedimenting population of membrane vesicles containing 5'-nucleotidase and acetylcholinesterase, a light membrane fraction containing myelin basic protein and 2',3'-cyclic nucleotide 3'-phosphodiesterase, and an intermediate membrane fraction containing the highest specific activity of 2',3'-cyclic nucleotide 3'-phosphodiesterase and a small proportion of myelin basic protein. Cyclic AMP stimulation of protein phosphorylation was confined to a protein of Mr 49 700, which co-electrophoresed with the upper component of the Wolfgram protein doublet. Cyclic AMP did not affect the phosphorylation of myelin basic protein. Cyclic AMP-stimulated phosphorylation of this protein followed 2',3'-cyclic nucleotide 3'-phosphodiesterase activity on subcellular fractionation and was correspondingly high in the intermediate or 'myelin-like' fraction on sucrose-density-gradient centrifugation.     

Protein kinases associated with peripheral nerve myelin. 1. Phosphorylation of endogenous myelin proteins and exogenous substrates.

When highly purified myelin from rat sciatic nerve was incubated with [gamma-32P]ATP, protein components of the membrane were phosphorylated indicating the presence of both the substrate (receptor protein) and an endogenous kinase in the membrane. Polyacrylamide gel electrophoresis of the phosphorylated membrane proteins followed by scintillation counting of gel slices and autoradiography showed that the polypeptides of molecular weights 28000, 23000 and 19000 were phosphorylated, and 32P from [gamma-32P]ATP having been incorporated into serine residues of the substrate proteins. Phosphorylation of purified myelin was Mg2+-dependent, was optimal at pH 6.5 and was not stimulated by adenosine 3',5'-monophosphate. We found that proteins other than those in myelin, such as phosvitin, casein, protamine and histones, can also act as a substrate for the membrane associated kinase. Muscle protein kinase inhibitor had no effect on the endogenous phosphorylation of myelin proteins or on the phosphorylation of phosvitin by peripheral nerve myelin protein kinase. However, the phosphorylation of histone by peripheral nerve myelin protein kinase was inhibited by the protein kinase inhibitor. After washing the membrane with 150 mM KCl the protein kinase that utilizes histone as substrate was found in the supernatant. In contrast, the endogenous phosphorylation of membrane proteins or the phosphorylation of phosvitin by the membrane associated kinase was not affected by washing. From these findings we conclude that at least two protein kinase systems exist in purified peripheral nerve myelin. One system is not inhibited by muscle kinase inhibitor, is tightly bound to the membrane and utilizes as its receptor proteins either exogenous phosvitin or endogenous membrane proteins. The second system is inhibited by muscle kinase inhibitor, is removable from the membrane and utilizes histones as its receptor proteins.     

Reactions of fluorescent probes with normal and chemically modified myelin basic protein and proteolipid. Comparisons with myelin.

Basic (encephalitogenic) protein and water-soluble proteolipid apoprotein isolated from bovine brain myelin bind 8-anilino-1-naphthalenesulfonate and 2-p-toluidinylnaphthalene-6-sulfonate with resulting enhancement of dye fluorescence and a blue-shift of the emission spectrum. The dyes had a higher affinity and quantum yield, when bound to the proteolipid (Kans=2.3x10--6,=0.67) than to the basic protein (Kans=3.3x10--5,=0.40). From the efficiency of radiationless energy transfer from trytophan to bound ANS the intramolecular distances were calculated to be 17 and 27 A for the proteolipid and basic protein, respectively. Unlike myelin, incubation with proteolytic enzymes (e.g., Pronase and trypsin) abolished fluorescence enhancement of ANS or TNS by the extracted proteins. In contrast to myelin, the fluorescence of solutions of fluorescent probes plus proteolipid was reduced by Ca-2+,not affected by La-3+, local anesthetics, or polymyxin B, and only slightly increased by low pH or blockade of free carboxyl groups. The reactions of the basic protein were similar under these conditions except for a two- to threefold increase in dye binding in the presence of La-3+, or after blockade of carboxyl groups. N-Bromosuccinimide oxidation of tryptophan groups nearly abolished native protein fluorescence, but did not affect dye binding. However, alkylation of tryptophan groups of both proteins by 2-hydroxy (or methoxy)-5-nitrobenzyl bromide reduced the of bound ANS (excited at 380 nm) to 0.15 normal. The same effect was observed with human serum albumin. The fluorescence emission of ANS bound to myelin was not affected by alkylation of membrane tryptophan groups with the Koshland reagents, except for abolition of energy transfer from tryptophan to bound dye molecules. This suggests that dye binding to protein is negligible in the intact membrane. Proteolipid incorporated into lipid vesicles containing phosphatidylserine did not bind ANS or TNS unless Ca-2+, La-3+, polymyxin B, or local anesthetics were added to reduce the net negative surface potential of the lipid membranes. However, binding to protein in the lipid-protein vesicles remained less than for soluble protein. Basic protein or bovine serum albumin dye binding sites remained accessible after equilibration of these proteins with the same lipid vesicles. It is proposed that in the intact myelin membrane the proteolipid is probably strongly associated with specific anionic membrane lipids (i.e., phosphatidylserine), and most likely deeply embedded within the lipid hydrocarbon matrix of the myelin membrane. Also, in the intact myelin membrane the fluorescent probes are associated primarily, if not solely with the membrane lipids as indicated by the binding data. This is particularly the case for TNS where the total number of myelin binding sites is three to four times the potential protein binding sites.     

Investigations on myelinogenesisin vitro: I. The occurrence of endogenous protein kinase and its role in the phosphorylation of myelin basic proteins in “Myelin-like membranes” isolated from cerebral cell cultures

The presence of a protein kinase capable of phosphorylating endogenous as well as exogenously added myelin basic proteins has been demonstrated in a myelin-like membrane fraction isolated from reaggregating and surface adhering, primary cultures of cells dissociated from embryonic mouse brain. Only the large and small components of myelin basic proteins were found to be phosphorylated when myelin-like membrane fraction was incubated with [-³²P]ATP. The protein kinase endogenous to the myelin-like membrane fraction was mainly of the cyclic AMP independent type. There was very little cyclic AMP dependent or cyclic GMP dependent protein kinase activities in this myelin-like fraction. Although the myelin basic proteins were the only endogenous proteins phosphorylated, protein kinase of the myelin-like membrane was capable of catalyzing the phosphorylation of exogenous substrates, such as histones.     

Localization of the basic protein and lipophilin in the myelin membrane with a non-penetrating reagent.

The localization of proteins in myelin was studied by the use of a non-penetrating reagent. Tritiated 4,4'-diisothiocyano-2,2'-ditritiostilbene disulfonic acid was used to label the isolated myelin membrane. The membrane was labelled, the basic protein and the hydrophobic protein, lipophilin, were isolated. After 10 min of exposure to the reagent, the specific activity of lipophilin was found to be 10 times greater than that of the basic protein. Water shock did not alter the specific activities. However, sonication increased the specific activity of lipophilin but not that of basic protein. When the isolated proteins were labelled with 3H-labelled 4,4'-diisothiocyano-2,2'-ditritiostilbene disulfonic acid, the specific activity of the basic protein was 10 times that of lipophilin. We concluded that the low specific activity of basic protein isolated from the labelled membrane was due to the inaccessible position of this protein in the membrane bilayer.     

Protein kinase associated with peripheral nerve myelin. 1. Phosphorylation of endogenous myelin proteins and exogenous substrates

When highly purified myelin from rat sciatic nerve was incubated with [γ-³²P]ATP, protein components of the membrane were phosphorylated indicating the presence of both the substrate (receptor protein) and an endogenous kinase in the membrane. Polyacrylamide gel electrophoresis of the phosphorylated membrane proteins followed by scintillation counting of gel slices and autoradiography showed that the polypeptides of molecular weights 28000, 23000 and 19000 were phosphorylated, and ³²P from [γ-³²P]ATP having been incorporated into serine residues of the substrate proteins. Phosphorylation of purified myelin was Mg²⁺-dependent, was optimal at pH 6.5 and was not stimulated by adenosine 3′,5′-monophosphate. We found that proteins other than those in myelin, such as phosvitin, casein, protamine and histones, can also act as a substrate for the membrane associated kinase. Muscle protein kinase inhibitor had no effect on the endogenous phosphorylation of myelin proteins or on the phosphorylation of phosvitin by peripheral nerve myelin protein kinase. However, the phosphorylation of histone by peripheral nerve myelin protein kinase was inhibited by the protein kinase inhibitor. After washing the membrane with 150 mM KCl the protein kinase that utilizes histone as substrate was found in the supernatant. In contrast, the endogenous phosphorylation of membrane proteins or the phosphorylation of phosvitin by the membrane associated kinase was not affected by washing.From these findings we conclude that at least two protein kinase systems exist in purified peripheral nerve myelin. One system is not inhibited by muscle kinase inhibitor, is tightly bound to the membrane and utilizes as its receptor proteins either exogenous phosvitin or endogenous membrane proteins. The second system is inhibited by muscle kinase inhibitor, is removable from the membrane and utilizes histones as its receptor proteins.     

The polyadenylated RNA directing the synthesis of the rat myelin basic proteins is present in both free and membrane-bound forebrain polyribosomes.

Free and membrane-bound polyribosomes were isolated from the forebrain of actively myelinating 24-day-old rats. The poly(A)+ RNA (polyadenylated RNA) extracted from both fractions was translated in vitro in reticulocyte lysates [Hall & Lim (1981) Biochem. J. 196. 327-336] in the presence or absence of a heterologous microsomal membrane fraction from dog pancreas. The rat myelin basic proteins synthesized in vitro were isolated by CM-cellulose chromatography and by immunoprecipitation with purified anti-(myelin basic protein) antibody. The large (mol.wt. 18 500) and small (mol.wt. 16 000) myelin basic proteins were translational products of poly(A)+ RNA from both free and membrane-bound polyribosomes. The identity of the myelin basic proteins was verified by analysis of peptides generated by the cathepsin D digestion of the immunoprecipitated proteins synthesized in vitro, in comparison with authentic rat myelin basic proteins. Although several other translational products of membrane-bound polyribosomal poly(A)+ RNA were modified when microsomal membranes were present during translation, molecular weights of the myelin basic proteins themselves were unchanged. The myelin basic proteins synthesized in vitro also did not differ significantly in size from the authentic myelin basic proteins, indicating that these membrane proteins are unlikely to be synthesized as substantially larger precursor molecules. The presence of the specific mRNA species on both free and membrane-bound polyribosomes is compatible with the extrinsic location of the myelin basic proteins on the cytoplasmic surface of the myelin membrane.     

The self-organization of lipids and proteins of myelin at the membrane interface. Molecular factors underlying the microheterogeneity of domain segregation

The advances over the last 10 years on the understanding of myelin heterogeneity are reviewed. The main focus is on the applicability of Langmuir monolayers, Langmuir-Blodgett films and some associated techniques to unravelling the behaviour of interfaces formed with all the components of a natural membrane. Lipid-protein lateral segregation appears as a major driving force to determine surface patterns that can change under compression from circular domains to two-dimensional fractal structures. The major proteins of the myelin membrane induce lateral segregation in an otherwise homogeneous surface formed by the mixture of total myelin lipids. The lipid and protein components appear to distribute in the surface domains according to their charge, compressibility and relative molecular weight: myelin proteins, ganglioside GM1 and fluorescent lipid probes partition into liquid-expanded phase domains; other components such as phosphatidylserine and galactocerebroside partition into another liquid phase enriched in cholesterol. Simplified protein-lipid mixtures allow assessment of the participation of the major proteins in the two dimensional pattern development. One of the major myelin proteins, the Folch-Lees proteolipid, self-segregates into, and determines formation of, fractal-like patterns. The presence of the second major protein, myelin basic protein, leads to round liquid-expanded domains in the absence of Folch-Lees proteolipid and softens the boundaries of the fractal structures in its presence. The location of myelin basic protein in the interface is surface pressure sensitive, being slightly squeezed out at high surface pressure, allowing the fractal domains enriched in Folch-Lees proteolipid to evolve.     

The in vivo synthesis of myelin proteins in rabbit sciatic nerve

Rabbits were injected into the sciatic nerves with either ³⁵S-methionine, or ³H-fucose. After times ranging from 45 min to 15 days the nerves were removed and the total particulate material from the nerves fractionated to give seven subfractions with densities between 0.2 and 1.2 M sucrose. The patterns of radio-labelled proteins were examined by SDS-PAGE and quantitative fluorography. The results showed that the P₂ basic protein was metabolically far more active than either the major P₀ glycoprotein, or the basic protein BP. The P₂ protein also entered the myelin fractions more rapidly than either P₀, or BP components. The net synthesis of P₀ was slower than P₂ and BP and this intrinsic membrane protein remained associated with the denser membrane fractions (>0.7 M sucrose) for longer than the basic proteins prior to entering myelin. Newly synthesized high molecular weight proteins remained concentrated in the denser membrane fractions and turned over faster than the myelin proteins.

A low density myelin fraction (B) was detected in which both the P₂ protein and certain high molecular weight proteins became more rapidly labelled than in compact myelin. In this fraction the specific activity remained higher than that of compact myelin for up to five days after the injection of ³⁵S-methionine into the nerve.

The results indicate that the major PNS myelin proteins are incorporated into and turn over in the various compartments of the Schwann cell plasma membrane—myelin continuum at very different rates.     

Calcium ion stimulated endogenous protein kinase catalyzed phosphorylation of basic proteins in myelin subfractions and myelin-like membrane fraction from rat brain

Polypeptide composition and endogenous phosphorylation were investigated in the subfractions of rat brain myelin isolated by either discontinuous or continuous sucrose density gradient centrifugation of myelin. Similarly, a myelin-like membrane fraction (SN4) was also studied. Observations were made that strongly indicated the presence of a calcium-stimulated protein kinase in a highly purified myelin preparation and which exclusively phosphorylated myelin basic proteins of the membrane preparation. Adenosine cyclic 3',5'-phosphate (cAMP) stimulated kinase on the other hand was found to be considerably enriched in the myelin-like membrane fraction. Although this latter enzyme is also capable of phosphorylating the basic proteins, its effect was at least 5 times weaker compared to the calcium-stimulated myelin protein kinase. Within the gradient subfractions there appeared a close relation between the amount of basic proteins and their calcium-stimulated phosphorylation; a similar relationship, however, was not obtained in the case of cAMP-dependent phosphorylation of myelin basic proteins. The former (i.e., Ca2+-stimulated phosphorylation) was found to require a protein factor that functionally resembled calmodulin. The results thus raises an interesting possibility of the presence of calmodulin-like proteins and a calcium-stimulated protein kinase in adult myelin membrane from mammalian brain, both of which have been hitherto unrecognized constituents of myelin membranes.     

ELECTROPHORETIC CHARACTERIZATION OF BASIC PROTEINS IN ACID EXTRACTS OF CENTRAL NERVOUS SYSTEM TISSUE

A technique has been outlined for identification of myelin basic proteins in mixtures of CNS proteins. Myelin basic proteins can be recognized easily by high cathodic mobility at low pH, a unique electrophoretic pattern exhibited at high pH and a characteristic colour when complexed with Amido black. The major protein extracted at pH 3·0 from either brain or spinal cord is myelin basic protein. In the low pH electrophoretic pattern of these extracts it is the most conspicuous component and the component migrating farthest cathodically; it does not appear in comparable electrophoretic patterns of liver extracts. Guinea pig myelin basic protein appears as a single dense blue-green band in low pH electrophoretic patterns, in contrast to the other proteins which are stained greyish-blue or greyish-purple by Amido black. The pattern of rat myelin basic protein is similar except that it consists of a pair of dense blue-green bands. A third characteristic which facilitates the identification of myelin basic proteins in mixtures is a considerable cathodic mobility and electrophoretic heterogeneity at pH 10·6. Most other basic CNS proteins barely penetrate the gel at this pH. We have also examined in detail the behaviour of two other components of pH 3·0 extracts which migrate close to myelin basic protein at low pH. Both are present in pH 3·0 extracts of liver and brain but not of spinal cord, and both stain grey instead of blue-green, a characteristic which readily distinguishes them from myelin basic protein. Neither of these components affects the characteristic pattern of microheterogeneity observed in high pH electrophoretograms of myelin basic proteins. One of these components has been purified and tentatively identified as lysine-rich histone F1.     

THE CHEMICAL COMPOSITION OF MYELIN IN ORGAN CULTURES OF RAT CEREBELLUM

Myelinating organ cultures of rat cerebellum were maintained in vitro for up to 130 days. Extensive myelination took place between 7 DIV (days in vitro) and 28 DIV. Centrifugation of a crude culture myelin fraction on a discontinuous gradient yielded three layers termed light myelin, heavy myelin and membrane fraction, which exhibited an ultrastructure virtually identical to that of comparable layers prepared from surviving littermates. However, culture myelin layers showed a gross deficiency of galactolipids with a relative increase in phospholipids. The 2,3′-cyclic nucleoside-monophosphate phosphodiesterase (CNP) activity was decreased in the culture myelin layers, but not to an extent comparable to the cerebroside deficiency. A form of “slow myelin maturation” takes place in vitro with both myelin cerebrosides and sulphatides increasing in cultures older than 60 DIV. The results indicate that CNS myelination comprises at least two phases, and that the second phase involving galactolipid enrichment of myelin can, under experimental conditions, be partly uncoupled from the first phase without affecting the morphology or ultrastructure of the sheaths.     

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.