Myelin Proteolipid Protein Contains Thioester-Linked Fatty Acids

Myelin proteolipid protein (PLP) is known to contain long-chain, covalently bound fatty acids. Previous studies, including our own, have suggested the occurrence of an oxyester type of linkage between fatty acids and PLP. However, we found that protein-SH groups are required in the acylation reaction, suggesting the possible presence of thioesters. In the present study, we have examined the nature of the acyl-PLP linkages by determining whether free thiol groups are generated on removal of fatty acids. Incubation of reduced and carboxyamidomethylated proteolipid apoprotein (RCM-APL) with 0.2 M hydroxylamine and [14C]iodoacetamide at pH 7.5 and 37 degrees C resulted in the release of fatty acids and the concomitant labeling of newly formed thiol groups. Incubation with Tris or methylamine at pH 7.5 failed to remove fatty acids and generate free -SH groups. The possibility that on treatment buried thiol groups became exposed was essentially excluded because (1) similar results were obtained in 2-chloroethanol, a solvent in which acylated and deacylated PLP have the same conformation, and (2) small PLP peptides were labeled only in the presence of hydroxylamine. On incubation with [14C]methylamine at pH 9.0, RCM-APL was not labeled, thus excluding the occurrence of intramolecular thiol esters. On the other hand, fatty acids were released as radioactive N-methyl fatty acylamide, indicating the presence of intermolecular thioesters between fatty acids and protein. These results demonstrate that a large proportion of fatty acids covalently bound to PLP are liked to -SH groups.     

Acylation of Rat Brain Myelin Proteolipid Protein with Different Fatty Acids

The acylation of rat brain proteolipid protein (PLP) with tritiated palmitic, oleic, and myristic acids was studied in vivo and in vitro and compared with the acylation of lipids. Twenty-four hours after intracranial injection of [3H]myristic acid, only 16% of the PLP-bound label appeared as myristic acid, with 66% as palmitic, 9% as stearic, and 6% as oleic acid, whereas greater than 63% of the label in total or myelin phospholipid was in the form of myristic acid. In contrast, after labelling with [3H]palmitic or oleic acids, 75% and 86%, respectively, of the radioactivity in PLP remained in the original form. When brain tissue slices were incubated for short periods of time, the incorporation of palmitic and oleic acids into PLP exceeded that of myristic acid by a factor of 8. In both systems and with all precursors studied, the label associated with PLP was shown to be in ester linkage. The results suggest a preferential acylation of PLP with palmitic and oleic acids as compared with myristic acid. This is consistent with the fatty acid composition of the isolated PLP.     

Recovery of Proteolipid Protein in Mice Heterozygous for the Jimpy Gene

We have measured levels and synthesis of proteolipid protein (PLP) and its transport into myelin in female mice heterozygous for the jimpy gene and in their normal female littermates. In both cord and cerebrum, jimpy carriers show deficits in PLP during development followed by compensation in adulthood. Recovery of PLP occurs earlier in cord than in brain. At 13 days levels of PLP in carriers compared to controls are reduced to 0.60 and 0.44, respectively, in cord and cerebrum. By 100 days, normal levels of PLP are attained in cord (1.13) whereas levels of PLP in cerebrum are only 0.78 of control. By 200 days full recovery occurs in cerebrum, with a ratio of 1.21, suggesting a possible over-compensation. The yield of myelin from cerebrum was reduced to 0.78 in carriers compared to controls at 17 days. In brain slices, incorporation of [3H]leucine into homogenate PLP from carriers is the same as in controls, whereas [3H]leucine incorporation into myelin PLP is reduced to 0.68 of control. These results indicate that synthesis of PLP in the carriers is normal at 17 days, but transport of PLP into myelin is reduced. Similarly, acylation of homogenate PLP is normal, whereas acylation of myelin PLP is reduced, as measured by incorporation of [3H]palmitic acid. Transport of PLP into myelin was compared to transport of MBP; transport of both proteins was equally decreased as indicated by the similar ratio of labeled PLP to MBP in myelin from carriers compared to noncarriers.(ABSTRACT TRUNCATED AT 250 WORDS)     

Intracellular Translocation of Myelin Proteolipid Protein

Brainstem slices prepared from 22-day-old rats were employed to study the intracellular translocation of radioactively labeled myelin proteolipid protein (PLP). Double-isotope and short pulse-chase procedures allowed us to demonstrate the flux of PLP through nine different subcellular membrane fractions that were isolated on the basis of their particle size and buoyant density. Tagged PLP was rapidly depleted from microsomes, showed transient passage through a number of presumably intermediate membranous pools, and accumulated in myelin. On the basis of the kinetics of PLP labeling and isotope ratios, the membranes can be arranged as they participate in the intracellular translocation of PLP and consistently show a pattern indicating possible precursor-product relationships.     

Fatty Acid Acylation of Rat Brain Myelin Proteolipid Protein In Vitro: Identification of the Lipid Donor

The immediate acyl chain donor for fatty acid esterification of proteolipid protein (PLP) was identified in an in vitro system. Rat brain total membranes, after removal of crude nuclear and mitochondrial fractions, were incubated with radioactive acyl donors, extracted with chloroform/methanol, and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. In the presence of [3H]palmitic acid, CoA, ATP, and Mg2+, acylation of endogenous PLP occurred at a linear rate for at least 2 h. The radioactivity was associated with the protein via an ester linkage, mainly as palmitic acid. Omission of ATP, CoA, Mg2+, or all three reduced fatty acid incorporation into PLP to 44, 27, 8, and 4%, respectively, of the values in the complete system. Incubation of the membrane fraction with [3H]palmitoyl-CoA in the absence of CoA and ATP led to highly labeled PLP. These data demonstrate that activation of free fatty acid is required for acylation. Phospholipids and glycolipids were not able to acylate the PLP directly. Finally, when isolated myelin was incubated with [3H]palmitoyl-CoA in the absence of cofactors, only PLP was labeled, thus confirming the identity of palmitoyl-CoA as the direct acyl chain donor and suggesting that the acylating activity and the PLP pool available for acylation are both in the myelin.     

Nitric Oxide Reduces the Palmitoylation of Rat Myelin Proteolipid Protein by an Indirect Mechanism

Brain slices from 20-day-old rats were incubated with [³H]palmitate for 2 hours in the absence or presence of the NO-donors S-nitroso-N-acetyl-penicillamine (SNAP), ethyl-2-[hydroxyimino]-5-nitro-3-hexeneamide (NOR-3), 4-phenyl-3-furoxan carbonitrile (PFC) and sodium nitroprusside (SNP). Each of these drugs reduced the incorporation of [³H]palmitate into myelin proteolipid protein (PLP) in a concentration-dependent manner, SNP being the most active. The effect of SNAP was prevented by the NO-scavenger PTIO (2-phenyl-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide). Furthermore, decayed-SNAP, sodium nitrite and N- nitrosopyrrolidine were inactive, suggesting that free NO and/or some of its direct oxidation products are the active molecular species. The amount of fatty acids bound to PLP and the rate of deacylation were unaffected by NO. Although NO diminished the number of thiols in brain and myelin proteins, with the formation of both nitrosothiols and disulfides, these changes did not parallel those in PLP acylation. In contrast, NO was effective at reducing the palmitoylation of brain and myelin lipids, and this effect along with that of PLP, was ascribed to a decrease in palmitoyl-CoA levels. The NO-induced reduction in acyl-CoA concentration was due to the decline in ATP levels, while the amount of [³H]palmitate incorporated into the tissue, the activity of palmitoyl-CoA ligase and palmitoyl-CoA hydrolase, and the concentration of CoASH were unaltered by the drugs. Experiments with endogenously-synthesized [¹⁸O]fatty acids confirmed that NO affects predominantly the ATP-dependent palmitoylation of PLP. In conclusion, the inhibitory action of NO on the fatty acylation of PLP is indirect and caused by energy depletion.     

Fatty Acid Composition of Myelin Proteolipid Protein During Vertebrate Evolution

The hydrophobic myelin proteolipid protein (PLP) contains covalently bound long-chain fatty acids which are attached to intracellular cysteine residues via thioester linkages. To gain insight into the role of acylation in the structure and function of myelin PLP, the amount and pattern of acyl groups attached to the protein during vertebrate evolution was determined. PLP isolated from brain myelin of amphibians, reptiles, birds and several mammals was subjected to alkaline methanolysis and the released methyl esters were analyzed by gas-liquid chromatography. In all species studied, PLP contained approximately the same amount of covalently bound fatty acids (3% w/w), and palmitic, palmitoleic, oleic and stearic acids were always the major acyl groups. Although the relative proportions of these fatty acids changed during evolution, the changes did not necessarily follow the variations in the acyl chain composition of the myelin free fatty acid pool, suggesting fatty acid specificity. The phylogenetic conservation of acylation suggests that this post-translational modification is critical for PLP function.     

Fatty Acid Composition of Human Myelin Proteolipid Protein in Peroxisomal Disorders

Myelin proteolipid protein (PLP) is an acylated protein which contains approximately 2 mol of ester-bound fatty acids. In this study, the amount and composition of fatty acids covalently bound to human myelin PLP were determined during development and in peroxisomal disorders. Palmitic, oleic, and stearic acids accounted for most of the PLP acyl chains. However, in contrast to PLP in other species, human PLP contains relatively more very long chain fatty acids (VLCFA). The fatty acid composition remained essentially unchanged between 1 day and 74 years of age. The total amount of fatty acid bound to PLP was not altered in any of the pathological cases examined. However, in the peroxisomal disorder adrenoleukodystrophy, the proportions of saturated and, to a lesser extent, monounsaturated VLCFA bound to PLP were increased at the expense of oleic acid. Smaller, but significant, changes were observed in adrenomyeloneuropathy. The reduction in the levels of oleic acid was also observed in two other peroxisomal disorders, the cerebrohepatorenal (Zellweger) syndrome and neonatal adrenoleukodystrophy, as well as in the lysosomal disorder Krabbe globoid cell leukodystrophy. However, in these disorders, the decrease in oleic acid occurred at the expense of stearic acid, and not VLCFA. The results indicate that, although a characteristic PLP fatty acid pattern is normally maintained, changes in the acyl chain pool can ultimately be reflected in the fatty acid composition of the protein. The altered PLP-acyl chain pattern in peroxisomal disorders may contribute to the pathophysiology of these devastating disorders.     

Electrophoretic Analysis of Myelin Proteolipid Protein and Its Deacylated Form

Myelin proteolipid protein is known to contain covalently bound fatty acid. To determine the contribution of the fatty acid to the multiple bands observed on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the electrophoretic parameters of the proteolipid protein were compared with those of the deacylated form. The relative mobility and proportion of each band, as well as the retardation coefficient and free electrophoretic mobility, were not altered by removal of the fatty acid moiety. Furthermore, the acylated and deacylated forms bound the same amounts of sodium dodecyl sulfate. These data demonstrate that the presence of covalently bound fatty acids does not account for the electrophoretic heterogeneity of the proteolipid.     

Decreased Fatty Acylation of Myelin Proteolipid Protein in the Twitcher Mouse

We examined chronological changes of myelin proteins of the brainstem and spinal cord of the twitcher mouse (15, 20, and 30 days old), a murine model of human globoid cell leukodystrophy caused by a genetic deficiency of galactosylceramidase I activity. The yield of myelin was normal until postnatal day 20, whereas galactosylsphingosine (psychosine) accumulated with age in myelin. The protein profiles of myelin and the activity of 2',3'-cyclic nucleotide 3'-phosphodiesterase in the myelin remained normal throughout the experimental period. Fatty acylation of proteolipid protein (PLP) was examined in a cell-free system by incubation of myelin with [3H]palmitic acid, CoA, and ATP, and was normal at postnatal day 15, but decreased after postnatal day 20. Decreased fatty acylation of PLP was also observed in the twitcher mouse at postnatal day 20 when the isolated myelin was incubated with [14C]palmitoyl-CoA in the absence of ATP and CoA, or the slices of brainstem and spinal cord were incubated with [3H]palmitic acid. The activity of fatty acid:CoA ligase was reduced in myelin. These data suggest that decreased acylation of PLP in twitcher mouse myelin is probably due to reduced activities for both activation and transfer of fatty acid into PLP and that metabolic disturbance is present in myelin because acylation of PLP has been shown to occur in myelin membrane. Although psychosine (200 microM) inhibited only 17% of the acylation in vitro, it may be responsible for the reduced acylation of PLP in vivo.     

Myelin Proteolipid Protein Gene Expression in Jimpy and Jimpymsd Mice

Proteolipid protein (PLP) gene expression was studied in the dysmyelinating mouse mutant jimpy(msd) (jpmsd; myelin synthesis deficient) and compared with that in wild-type mice and the allelic mutant, jimpy (jp). Southern analyses of genomic DNA from jpmsd mice revealed no major rearrangements of the PLP gene relative to the wild-type mouse PLP gene. PLP-specific mRNA levels were significantly reduced in these mutant mice, although both the 3.2- and 2.4-kilobase PLP-specific mRNAs were seen. Also, no size differences in either PLP or DM20 mRNAs were found by S1 nuclease assays of brain RNA from either jpmsd or wild-type mice. Both PLP and DM20 protein were detectable at low levels in jpmsd brain homogenates, and these proteins comigrated with PLP and DM20 protein from normal mice. Western analyses showed an altered PLP:DM20 ratio in jpmsd mice relative to wild-type mice; DM20 levels exceeded PLP levels. It is surprising that a similar pattern of expression was seen in normal mice at less than 10 days of age: DM20 protein expression preceding PLP expression. Thus, jpmsd mice are capable of synthesizing normal PLP and DM20 protein; however, the PLP gene defect has affected the normal developmental pattern of expression for these two proteins.     

Conservation of the Carboxyl Terminal Epitope of Myelin Proteolipid Protein in the Tetrapods and Lobe-Finned Fish

Immunochemical analysis of the myelin proteolipid protein (PLP) has identified the carboxyl terminal amino acid phenylalanine 276 as the only PLP epitope conserved between the PLP components of rat and lungfish, species representing the phylogenetically most widely separated groups that synthesise typical CNS myelin. Immunoblotting using a rabbit antiserum raised against the carboxyl terminal sequence of rat PLP (residues 257-276) identified this epitope on the PLP components of both tetrapod (rat, chicken, lizard, and frog) and lobe-finned fish (coelacanth and lungfish) CNS myelin, including the DM-20 isoform of PLP, which is restricted to rat, chicken, and lizard CNS myelin. The conservation of the carboxyl terminus of PLP during evolution suggests this structure may play an important role in maintaining the organisation and function of PLP in the myelin membrane.     

Presence of Proteolipid Protein in Coelacanth Brain Myelin Demonstrates Tetrapod Affinities and Questions a Chondrichthyan Association

The protein and glycoprotein compositions of CNS myelin from the living coelacanth (Latimeria chalumnae) were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. An unglycosylated component of 25 kilodaltons showed substantially stronger immunoblot reactivity with antibodies against mammalian proteolipid protein (PLP) than lungfish glycosylated PLP. DM-20 (intermediate protein) was not detectable in either fish. The presence of unglycosylated PLP in CNS myelin of the actinistian coelacanth contradicts an association with cartilaginous fishes but supports tetrapod affinities closer than those of lungfish.     

Monoclonal Antibodies Against Myelin Proteolipid Protein: Identification and Characterization of Two Major Determinants

This report describes the preparation and characterization of a panel of monoclonal antibodies (mAbs) against the myelin proteolipid protein (PLP). A Lewis rat was immunized with bovine proteolipid apoprotein and 27 mAbs were selected based on their reactivity against bovine PLP on enzyme-linked immunosorbent assays. Eleven mAbs recognized the PLP carboxyl-terminal sequence when tested against a panel of synthetic peptides in a solid-phase assay. A carboxyl-terminal pentapeptide (residues 272-276) was sufficient for antibody binding and the terminal phenylalanine residue was found particularly important. Deletion, modification, or replacement of this residue markedly reduced or obliterated antigen-antibody interaction. Nine mAbs reacted with a second antigenic determinant, residues 209-217, but these could be identified only by competitive immunoassays. This peptide was a more effective inhibitor than the longer peptides 202-217 and 205-221, suggesting that flanking residues may interfere with peptide-antibody interaction. Seven antibodies did not react with any of the synthetic peptides tested and their determinants remain unidentified. Immunoblot analysis showed that the mAbs reacted with both the PLP and the DM-20 isoforms. Twenty-three of the mAbs were of the immunoglobulin G2a or b isotype; the remaining antibodies were immunoglobulin M and all of these were specific for residues 209-217. Cultured murine oligodendrocytes were stained by most of the mAbs tested, but the most intense reactivity was observed with the carboxyl-terminus-specific mAbs. The immunocytochemical analyses demonstrate that the mAbs react with the native PLP in situ and show their potential usefulness for studies of the cell biology of myelin and oligodendrocytes.     

A Single Nucleotide Difference in the Gene for Myelin Proteolipid Protein Defines the Jimpy Mutation in Mouse

We have previously shown that, in the myelin-deficient jimpy mutant mouse, 74 nucleotides are absent from the mRNA for proteolipid protein (PLP) as a result of aberrant RNA processing. To define the exact site of the jimpy mutation, we have analyzed the PLP gene obtained from a jimpy mouse genomic library. We find that the nucleotide sequence that is absent from jimpy PLP mRNA is fully preserved in the jimpy PLP gene. The missing segment corresponds to a separate exon, equivalent to exon 5 of the human PLP gene. The nucleotide sequence at the 3' end of intron 4 in the jimpy PLP gene contains a single point mutation. A base change A----G in the 3' acceptor splice site has altered a position that is 100% conserved in all published splice acceptor sequences. We conclude that the primary genetic defect of the jimpy mouse is a single base change in the PLP gene disabling an invariant recognition sequence of RNA splicing.     

Structure of the Proteolipid Protein Extracted from Bovine Central Nervous System Myelin with Nondenaturing Detergents

As a basis for attempts to define the structures of the proteins within myelin, methods have been developed for their extraction and isolation in solutions of non-denaturing detergents. With use of solutions of deoxycholate or Triton X-100, up to 90% of the protein has been extracted from bovine CNS myelin, along with most of the phospholipid. The proteolipid protein has been purified in deoxycholate solutions by chromatography on a blue dye-ligand column, which retained all of the basic protein and 2',3'-cyclic nucleotide-3'-phosphodiesterase, and then on Sephacryl S300, which separated proteolipid protein from phospholipid and high-molecular-weight proteins. The proteolipid protein was isolated from Triton X-100 extracts of myelin by adsorption onto phosphocellulose resin, with subsequent elution by 0.5 M sodium chloride. Gel permeation chromatography was used as the final purification step. Sedimentation equilibrium experiments gave a monomer molecular weight of 134,000 +/- 8000 in deoxycholate and 145,000 +/- 17,000 in Triton X-100 solutions. On the basis of an apparent subunit molecular weight of 23,500 it was deduced that the native protein is probably hexameric. Above 0.2 gL-1 in Triton X-100 solutions and 0.5 gL-1 in deoxycholate solutions the protein aggregated. In deoxycholate solutions the protein adopts the highly helical conformation expected for an intrinsic membrane protein.     

Major Central Nervous System Myelin Glycoprotein of the African Lungfish (Protopterus dolloi) Cross-Reacts with Myelin Proteolipid Protein Antibodies, Indicating a Close Phylogenetic Relationship with Amphibians

CNS myelin was isolated from the spinal cord of the African lungfish Protopterus dolloi. Its proteins consisted of (1) two basic proteins (16,000 and 18,500 apparent Mr) that reacted with anti-human CNS myelin basic protein antibodies and (2) a major protein (29,000 apparent Mr) that stained with concanavalin A-horseradish peroxidase and bound to anti-rat CNS myelin proteolipid protein (PLP) antibodies. This dominant 29,000 Mr protein showed no reaction with antibodies against the major bovine PNS myelin glycoprotein P0. Following treatment with endoglycosidase F the 29,000 Mr protein was reduced in size to a 26,000 apparent Mr component that no longer bound concanavalin A but retained the anti-PLP reactivity. These results agree with a concanavalin A-binding oligosaccharide linked through asparagine to a protein backbone of PLP homology. The major 29,000 Mr lungfish CNS myelin protein was therefore termed g-PLP (glycosylated proteolipid protein). This is the first report demonstrating the occurrence of a PLP-cross-reactive protein in CNS myelin of a fish. It attests to the close phylogenetic relationship of lungfishes to amphibians. Amphibians were previously recognized as the oldest class bearing PLP in its CNS myelin.     

The Myelin-Deficient Rat Has a Single Base Substitution in the Third Exon of the Myelin Proteolipid Protein Gene

Several genetic disorders that occur in animals and in humans result in an inability to synthesize normal myelin. Some of these disorders are inherited in an X-linked manner. The localization of the myelin proteolipid protein (PLP) gene to the X chromosome has directed the study of X-linked myelination disorders toward PLP. The myelin-deficient rat is one such X-linked dysmyelinating mutant. From a cDNA library constructed from myelin-deficient rat brain mRNA, we have isolated and sequenced cDNAs corresponding to PLP and its alternatively spliced isoform, DM-20. An A to C transition was detected in these cDNAs, which results in a threonine to proline change at amino acid 74 in both PLP and DM-20. No other substitutions were seen in the cDNA sequences. Polymerase chain reaction amplification and sequencing of the corresponding genomic regions were used to confirm the single base change. This substitution occurs in a highly hydrophobic portion of the protein that is thought to be an alpha-helical transmembrane segment. The presence of a helix-breaking amino acid such as proline in this segment is likely to influence the ability of the protein to interact with the membrane.     

Characterizaton and Biosynthesis of the Plasma Membrane Proteolipid Protein in Neural Tissue

In this study we have characterized, in brain, the expression of a plasma membrane proteolipid protein (PM-PLP) complex that can form cation-selective channels in lipid bilayers. We isolated PLP fractions from synaptic plasma membrane and glial microsomes and found a high degree of similarity in both size and amino acid composition to the complex we had previously isolated from kidney. Antibodies specific to the kidney PM-PLP were prepared, and, on the basis of immunoblot and immunoprecipitation studies, the PM-PLP complex isolated from neural membranes was shown to be immunologically related to the kidney PM-PLP. These proteolipid proteins exhibited a molecular weight of approximately 14K and contained a high percentage of hydrophobic amino acids with an apparent absence of cysteine. The biogenesis of PM-PLP in brain was studied by in vitro translation of free and bound polysomes and total RNA in a rabbit reticulocyte lysate followed by immunoprecipitation of the translation products. From these studies it is concluded that the PM-PLP complex is synthesized on the rough endoplasmic reticulum. On the basis of the identical electrophoretic mobility of material isolated from plasma membranes and material immunoprecipitated after translation of bound polysomes and isolated RNA, it appears that the PM-PLP does not undergo detectable posttranslational processing between its site of synthesis and its incorporation into the plasma membrane.