Large Scale Preparation of Myelin Basic Protein from Central Nervous Tissue of Several Mammalian Species

The wide-spread use of and demand for myelin basic protein for immunologic studies has prompted us to re-examine the details of its isolation from CNS tissue of various species. The procedure described in this communication for the isolation and purification of myelin basic protein does not require column chromatography and is therefore suitable for large scale preparation of a reasonably pure product with simple laboratory equipment. If certain precautions are taken, the yield and quality of the product are reproducible. Certain contaminants which may accompany myelin basic protein during purification by procedures currently in use are pointed out, and their possible influence on the immunologic behavior of myelin basic protein is discussed. Suitable electrophoretic techniques for the detection of these contaminants as well as details for their removal from the myelin basic protein are described.     

Covalent linkage of phospholipid to myelin basic protein: identification of serine-54 as the site of attachment

The peptide portion of the lipopeptide isolated from bovine myelin basic protein contained glycine, lysine, and serine in a 2:1:1 molar ratio as determined by amino acid analysis. The N-terminus of the peptide was determined to be glycine. The tetrapeptide Gly53-Ser-Gly-Lys56 was the only segment of myelin basic protein that matched the above two characteristics. This tetrapeptide is highly conserved among the myelin basic proteins sequenced so far. After the selective degradation of the lipopeptide, phosphoserine was identified in the acid hydrolysate, thus indicating that Ser-54 of myelin basic protein in bovine brain is the site of attachment of polyphosphoinositide. Interestingly, serine-54 of myelin basic protein can be phosphorylated by the endogenous protein kinase myelin. However, myelin basic protein phosphorylated by the catalytic subunit of an exogenous soluble protein kinase failed to produce radioactively labeled lipopeptide. Hence the endogenous enzymes of myelin are thought to be involved in the formation of the covalent linkage between polyphosphoinositide and myelin basic protein. The conservation in sequence suggests a possible important structural role for the "phospholipidation" of myelin basic protein.     

Stoichiometric relation of protein components in cerebral myelin from different species

Abstract— In cerebral myelin from man, ox, rabbit, guinea pig and chicken, the amounts of proteolipid protein, basic protein and the fraction of further protein components were found to be present in a fixed ratio of 5·0: 3·5: 2·0 by weight. The molecular weights of 25,000 and 35,000 as obtained for the basic protein and proteolipid protein might indicate that cerebral myelin contains one molecule of basic protein per molecule of proteolipid protein. This fixed ratio of protein components was found to be changed in myelin from the PNS and in cerebral myelin from rat and carp, with their exceptional basic proteins. Using the polyacrylamide-gel electrophoresis it was possible to demonstrate that a homogeneous structural protein (the Folch-Lees proteolipid protein) constitutes about 50 percent of the total amount of myelin proteins in all species studied. An attempt was made to correlate myelin protein and lipid patterns from various species.     

Effect of chemical modifications of myelin basic protein on its interaction with lipid interfaces and cell fusion ability

Summary The ability of native and chemically modified myelin basic protein to induce fusion of chicken erythrocytes and to interact with lipids in monolayers at the air-water interface and liposomes was studied. Chemical modifications of myelin basic protein were performed by acetylation and succinylation: the positive charges of the native protein were blocked to an extent of about 90–95%.Cellular aggregation and fusion of erythrocytes into multinucleated cells was induced by the native myelin basic protein. This effect was diminished for both acetylated and succinylated myelin basic protein. Native myelin basic protein penetrated appreciably in sulphatide-containing lipid monolayers while lower penetration occurred in monolayers of neutral lipids. Contrary to this, both chemically modified myelin basic proteins did not show any selectivity to penetrate into interfaces of neutral or negatively charged lipids. The intrinsic fluorescence of the native and chemically modified myelin basic proteins upon interacting with liposomes constituted by dipalmitoylphosphatidycholine, glycosphingolipids, egg phosphatidic acid or dipalmitoylphosphatidyl glycerol was studied. The interaction with liposomes of anionic lipids is accompanied by a blue shift of the maximum of the native protein emission fluorescence spectrum from 346 nm to 335 nm; no shift was observed with liposomes containing neutral lipids. The acetylated and succinylated myelin basic proteins did not show changes of their emission spectra upon interacting with any of the lipids studied. The results obtained in monolayers and the fluorescence shifts indicate a lack of correlation between the ability of the modified proteins to penetrate lipid interfaces and the microenvironment sensed by the tryptophan-containing domain.Abbreviations MBP myelin basic protein - DPPC dipalmitoyl phosphatidylcholine - DPPG dipalmitoyl phosphatidylglycerol - PA phosphatidic acid     

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 Presence of Aldehyde-Reacted Proteins in Normal and Multiple Sclerosis White Matter

The incorporation of tritium from NaB3H4 into the major protein components of myelin and the presence of weak fluorescence emission bands at wavelengths of approximately 440 and 500 nm from sodium dodecyl sulfate-solubilized, delipidated white matter are indicative of the presence of the products of aldehyde reactions with proteins. The incorporation of tritium from NaB3H4 into myelin proteins was confirmed by reaction with purified components of myelin basic protein or with lipophilin, a purified fraction of proteolipid protein. From the extent of tritium incorporation into the purified proteins, it is estimated that approximately 0.2 mol of tritium is incorporated/mol of myelin basic protein and approximately 0.4 mol of tritium/mol of proteolipid protein. There is approximately 50% greater incorporation of tritium into a more degraded, less positively charged form of the basic protein. The incorporation of tritium into normal and multiple sclerosis white matter was compared. There is a small but statistically significant difference in the percentage of the total counts incorporated into the major protein fractions for the two groups, with the multiple sclerosis samples showing a higher percentage of the counts in the Wolfgram protein and a lower percentage in the myelin basic protein compared with the normal samples.     

Phosphoprotein phosphatases for myelin basic protein in myelin and cytosol fractions of brain.

Phosphoprotein phosphatase (phosphoprotein phosphohydrolase EC 3.1.3.16) activity for myelin basic protein was found to be present in the myelin fraction of rat brain. The enzyme activity was in a latent form and solubilized by 0.2% Triton X-100 treatment with about 50% increase of activity. The cytosol fraction from bovine brain also had phosphoprotein phosphatase activity for myelin basic protein, which was resolved into at least two peaks of activity on DEAE-cellulose column chromatography. Myelin basic protein was the best substrate for both the solubilized myelin fraction and the cytosol enzymes among the substrate proteins tested. The Km values of the solubilized myelin fraction were 4.2 muM for myelin basic protein, 7.4 muM for arginine-rich histone, 8.0 muM for histone mixture and 14.3 muM for protamine, respectively.     

The Effect of the Shiverer Mutation on Myelin Basic Protein Expression in Homozygous and Heterozygous Mouse Brain

We report (a) that the shiverer mutation has pleiotropic phenotypic effects on myelin basic protein expression in the CNS of homozygous (shi/shi) mice and (b) that each of the effects of the shiverer allele is expressed co-dominantly with the wild-type allele in heterozygous (+/shi) animals. First, the total amount of myelin basic protein, as determined by radioimmunoassay, that accumulates in the CNS is approximately 0.1% of the wild-type amount in shi/shi animals and approximately 50% in +/shi animals. Second, the four major forms of myelin basic protein, with molecular weights of 21,500, 18,500, 17,000, and 14,000, that are present in wild-type mouse CNS are undetectable in either whole brain or purified myelin of shi/shi animals, and each of the four proteins is reduced commensurately in brain and myelin of +/shi animals. Third, the small amount of myelin basic protein-related material that does accumulate in the shi/shi brain consists of several polypeptides, with molecular weights ranging from 25,000 to 100,000, the pattern of which is different from that found in wild-type brain. The pattern of myelin basic protein-related polypeptides in +/shi brain is a composite of the wild type and the shiverer mutant. Fourth, messenger RNA from shi/shi brain, when translated in vitro, encodes a set of myelin basic protein-related polypeptides qualitatively similar to that encoded by wild-type messenger RNA, except that the 18,500 and 14,000 translation products are greatly reduced, while other myelin basic protein-related translation products are spared. The pattern of myelin basic protein-related translation products for +/shi messenger RNA is intermediate between the patterns for +/+ and shi/shi messenger RNAs. The results suggest that the genetic lesion in the shiverer mutation impinges on the structural gene (or genes) encoding myelin basic protein or on a cis-acting regulatory element controlling that gene (or genes).     

Lipid/myelin basic protein multilayers. A model for the cytoplasmic space in central nervous system myelin

A multilayered complex forms when a solution of myelin basic protein is added to single-bilayer vesicles formed by sonicating myelin lipids. Vesicles and multilayers have been studied by electron microscopy, biochemical analysis, and X-ray diffraction. Freeze-fracture electron microscopy shows well-separated vesicles before myelin basic protein is added, but afterward there are aggregated, possibly multilayered, vesicles and extensive planar multilayers. The vesicles aggregate and fuse within seconds after the protein is added, and the multilayers form within minutes. No intra-bilayer particles are seen, with or without the protein. Some myelin basic protein, but no lipid, remains in the supernatant after the protein is added and the complex sedimented for X-ray diffraction. A rather variable proportion of the protein is bound. X-ray diffraction patterns show that the vesicles are stable in the absence of myelin basic protein, even under high g-forces. After the protein is added, however, lipid/myelin basic protein multilayers predominate over single-bilayer vesicles. The protein is in every space between lipid bilayers. Thus the vesicles are torn open by strong interaction with myelin basic protein. The inter-bilayer spaces in the multilayers are comparable to the cytoplasmic spaces in central nervous system myelins . The diffraction indicates the same lipid bilayer thickness in vesicles and multilayers, to within 1 A. By comparing electron-density profiles of vesicles and multilayers, most of the myelin basic protein is located in the inter-bilayer space while up to one-third may be inserted between lipid headgroups. When cytochrome c is added in place of myelin basic protein, multilayers also form. In this case the protein is located entirely outside the unchanged bilayer. Comparison of the various profiles emphasizes the close and extensive apposition of myelin basic protein to the lipid bilayer. Numerous bonds may form between myelin basic protein and lipids. Cholesterol may enhance binding by opening gaps between diacyl-lipid headgroups.     

Myelin Membrane Assembly Is Driven by a Phase Transition of Myelin Basic Proteins Into a Cohesive Protein Meshwork

Rapid conduction of nerve impulses requires coating of axons by myelin. To function as an electrical insulator, myelin is generated as a tightly packed, lipid-rich multilayered membrane sheath. Knowledge about the mechanisms that govern myelin membrane biogenesis is required to understand myelin disassembly as it occurs in diseases such as multiple sclerosis. Here, we show that myelin basic protein drives myelin biogenesis using weak forces arising from its inherent capacity to phase separate. The association of myelin basic protein molecules to the inner leaflet of the membrane bilayer induces a phase transition into a cohesive mesh-like protein network. The formation of this protein network shares features with amyloid fibril formation. The process is driven by phenylalanine-mediated hydrophobic and amyloid-like interactions that provide the molecular basis for protein extrusion and myelin membrane zippering. These findings uncover a physicochemical mechanism of how a cytosolic protein regulates the morphology of a complex membrane architecture. These results provide a key mechanism in myelin membrane biogenesis with implications for disabling demyelinating diseases of the central nervous system.     

Cell lineage analysis of Schwann cells in the PNS determined by shiverer-normal mouse chimeras

The myelin of the peripheral nervous system from the shiverer mutant mice is characterized by the absence of myelin basic protein, while the other myelin protein components are present at normal levels. Myelin lamella formation is normal in the shiverer mutant. Therefore, by using antiserum against myelin basic protein, we can distinguish the shiverer from the wild-type control myelin immunohistochemically. To study the cell lineage of Schwann cells, chimeras produced by the aggregation of eight-cell embryos from wild-type mice and shiverer mice have been used. Using myelin basic protein as a marker, it was observed that Schwann cells in the sciatic nerve existed as patches of cells with like-genotype. The patches occurred in a linear array along the axons with some intermingling of Schwann cells. Complete randomization by intermingling of Schwann cells was not observed and clones of Schwann cells may persist as contiguous groups throughout peripheral nerve development.     

In Vivo Methylation of an Arginine in Chicken Myelin Basic Protein

Abstract: The amino acid sequence around the sole methylarginine residue in chicken myelin basic protein was determined and was found to be similar to that previously reported for mammalian myelin basic protein. The ratio N ^G, N '^G-dimethylarginine: N ^G-monomethylarginine:arginine was approximately 1.3:0.9:1.0. No N ^G, N ^G-dimethylarginine was detected in the protein. The in vivo incorporation of methyl groups from [methyl-³H]methionine into methylarginines in myelin was found to occur readily in 2-day-old chickens. Radioactively labelled N ^G, N '^G-dimeth-ylarginine and N ^G-monomethylarginine in myelin were derived solely from myelin basic protein. Radioactivity was also incorporated into N ^G, N ^G-dimeth-ylarginine, although this was not derived from myelin basic protein. As N ^G-monomethylarginine was easily separated from the dimethylarginines, and as it was derived from myelin basic protein, it may be a good marker for myelin basic protein turnover in vivo. A time course study of the incorporation showed that radioactivity was incorporated into N ^G-monomethylarginine up to 6 h after injection, and decayed slowly, with an apparent half-life of about 40 days.     

Cloned proteolipid protein and myelin basic protein cDNA. Transcription of the two genes during myelination

cDNA clones of rat brain proteolipid protein (PLP), also named lipophilin, the major integral myelin membrane protein, and of myelin basic protein (MBP), the major extrinsic myelin protein, have been isolated from a rat brain cDNA library cloned into the PstI site of pBR322. Poly(A)+ RNA from actively myelinating 18-day-old rats has been reversely transcribed. Oligonucleotides synthesized according to the established amino-acid sequence of lipophilin and the nucleotide sequence of the small myelin basic protein of the N-terminal, the central and C-terminal region of their sequences were used as hybridization probes for screening. The largest insert in one of several lipophilin clones was 2,585 base pairs (bp) in length (pLp 1). It contained 521 bp of the C-terminal coding sequence and the complete 2,064 bp long non-coding 3' sequence. The myelin basic protein cDNA insert of clones pMBP5 and pMBP6 is 2,530 bp long and that of clones pMBP2 and pMBP3 640 bp. These clones were also characterized. pMBP2 was sequenced and used together with the lipophilin cDNA clones as hybridization probes to estimate the lipophilin and myelin basic protein mRNA levels of rat brain during the myelination period. The expression of the lipophilin and myelin basic protein genes during development of the myelin sheath appears to be strictly coordinated.     

The action of snake venom, phospholipase A and trypsin on purified myelin in vitro.

1. Purified myelin was incubated with snake venom or phospholipase A in the presence of or absence of trypsin at 37 degrees C, pH7.4, for different times. 2. Analysis of the myelin pellet obtained after centrifugation of the myelin sample incubated with snake venom or phospholipase A alone showed conversion of phosphatidylcholine, phosphatidylethanolamine and phosphatidylserine into their corresponding lyso compounds. No significant loss of myelin protein was observed in these samples. 3. A marked digestion of basic proteins and proteolipid protein was observed from the myelin pellet when trypsin was present in the incubation mixture. 4. The digestion of basic protein and particularly of proteolipid from myelin suggest that phospholipases may make protein more exposed to proteolytic enzyme for its digestion. 5. The relevance of the co-operative effect of phospholipases and proteinases as a model system of the mechanism of myelin breakdown in degenerative brain diseases is discussed.     

Colvalent linkage of phospholipid to myelin basic protein: identification of phosphatidylinositol bisphosphate as the attached phospholipid

Evidence presented demonstrates a covalent attachment of a phospholipid to bovine myelin basic protein. Partial characterization of the phospholipid moiety was performed on myelin basic protein obtained from 32P-phosphorylated whole myelin that was first delipidated by two ether/ethanol (3:2 v/v) extractions, ether extraction, and acetone extraction and then purified by preparative sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. The myelin basic protein was precipitated with aqueous acetone and treated with proteases. Treatment with carboxypeptidase Y or trypsin for several hours released a lipophilic fragment, which was purified by reverse-phase high-performance liquid chromatography to yield two "lipopeptides". Such lipopeptides were obtained from both the major and minor myelin basic proteins of rat and bovine brain. Treatment with either mild base or phospholipase C removes the lipophilic character of the peptide fragment. The lipophilic fragment is a substrate for phospholipase D, but it does not comigrate on thin-layer chromatography with any 32P-labeled lipid obtained from myelin incubated with [gamma-32P]ATP. Polyphosphoinositides were shown to be released by mild acid treatment of myelin basic protein that had been extracted with organic solvent and then purified by SDS-polyacrylamide gel electrophoresis. Along with the fact that inositol monophosphate was identified in the partial acid hydrolysate of the lipopeptide, we have concluded that polyphosphoinositide (phosphatidylinositol 4-phosphate and/or phosphatidylinositol 4,5-bisphosphate) was the original phospholipid portion of the lipopeptide.     

Electron Microscopic Immunocytochemical Localization of Myelin Proteolipid Protein and Myelin Basic Protein to Oligodendrocytes in Rat Brain During Myelination

Electron microscopic immunocytochemical studies were carried out to localize myelin basic protein and myelin proteolipid protein during the active period of myelination in the developing rat brain using antisera to purified rat brain myelin proteolipid protein and large basic protein. The anti-large basic protein serum was shown by the immunoblot technique to cross-react with all five forms of basic protein present in the myelin of 8-day-old rat brain. Basic protein was localized diffusely in oligodendrocytes and their processes at very early stages in myelination. The immunostaining for basic protein was not specifically associated with any subcellular structures or organelles. The ultrastructural localization of basic protein suggests that it may be involved in fusion of the cytoplasmic faces of the oligodendrocyte processes during compaction of myelin. Immunoreactivity in the oligodendrocyte and myelin due to proteolipid protein appeared at a later stage of myelination than did that due to basic protein. Staining for proteolipid protein in the oligodendrocyte was restricted to the membranes of the rough endoplasmic reticulum, the Golgi apparatus, and apparent Golgi vesicles. The early, uncompacted periaxonal wrappings of oligodendrocyte processes were well stained with antiserum to large basic protein whereas staining for proteolipid protein was visible only after the compaction of myelin sheaths had begun. Our evidence indicates that basic protein and proteolipid protein are processed differently by the oligodendrocytes with regard to their subcellular localization and their time of appearance in the developing myelin sheath.     

Differences in Susceptibility of MBP Charge Isomers to Digestion by Stromelysin-1 (MMP-3) and Release of an Immunodominant Epitope

Charge microheterogeneity of myelin basic protein is known to affect its conformation and function. Here, the citrullinated myelin basic protein charge isomer, component-8, was shown to be more susceptible to stromelysin-1 cleavage than myelin basic protein component-1. Since levels of component-8 are increased in multiple sclerosis brain, the increased susceptibility of component-8 to proteolytic digestion may play a role in the pathogenesis of multiple sclerosis. Interestingly, component-1 isolated from multiple sclerosis patients was digested at a faster rate by stromelysin-1 than component-1 isolated from normal individuals. The reason for this difference is not clear, but likely reflects conformational differences between the two proteins as a result of post-translational modifications. Stromelysin-1 was able to cleave myelin basic protein in the presence of lipids and within the context of myelin and released several peptides including peptides containing the immunodominant epitope.     

The induction of liposome aggregation by myelin basic protein

Myelin basic protein derived from bovine spinal cord has been interacted with liposomes of varying brain lipid compositions. The effects of salt and protein concentration on liposome cross linking has been investigated. It appears that myelin basic protein cannot link liposomes composed of brain-derived phosphatidyl choline. Myelin basic protein can link liposomes composed of phosphatidyl serine; phosphatidyl serine + cholesterol; phosphatidyl serine + cholesterol + cerebroside sulphate. Linking of liposomes occurs at protein concentrations lower than those required for myelin basic protein dimers to be formed. Therefore, it seems that the monomeric form of myelin basic protein links lipid bilayers. The presence of cholesterol in the bilayer increases the ability of myelin basic protein to aggregate such liposomes compared with the linking ability of the polycationic polypeptide, poly-l-lysine.     

STUDIES ON THE MECHANISM OF DEMYELINATION: MYELIN AUTOLYSIS IN NORMAL AND EDEMATOUS CNS TISSUE

The effects on myelin of autolysis in situ after death and after purification were studied in normal brains and spinal cords and in those made edematous as a result of chronic triethyl tin (TET) feeding. Myelin prepared from normal and edematous brains and spinal cords autolyzed for 12 h at 4°C contained only slightly less basic protein than that prepared from freshly killed animals. The amounts of a light lipid-protein fraction (dissociated myelin) usually obtained during purification of myelin from edematous CNS were about the same in tissue from freshly killed rats and those autolyzed for 12 h at 4°C. Autolysis for 12 h at room temperature resulted in formation of large amounts of dissociated myelin and loss of basic protein, but more dissociation and basic protein loss occurred in CNS from edematous brains and spinal cords than from the normal. Purified myelin prepared from freshly-killed normal and TET-fed rats was incubated at 37°C in media of several ionic strengths. In Krebs-Ringer bicarbonate (physiological extracellular fluid) extensive dissociation of myelin occurred with much less in 0.04 M-Tris buffer, pH 7.2, and only small amounts were formed in 0.01 M-Tris. In all cases myelin from edematous CNS formed more dissociated fraction than did the normal myelin. Basic protein loss was also proportional to the ionic strength of the media, but there was no difference in loss between normal and TET-myelin. Two different factors, proteolysis and physical extraction of basic protein by salt solutions, may be contributing to myelin dissociation and loss of basic protein.