In vivo acylation of proteolipid protein and DM-20 in myelin and myelin subfractions of developing rat brain: Immunoblot identification of acylated PLP and DM-20

The acylation of proteolipid protein (PLP) was examined in myelin and myelin subfractions from rat brain during the active period of myelination. Proteolipid protein and DM-20 in myelin and myelin subfractions were readily acylated in developing rat brain 22 hours after intracerebral injection of [3H]palmitic acid. No differences in the relative specific activity of PLP in myelin from 9-, 15-, and 30-day-old rat brains was observed; however, the relative specific activity of PLP in the heavy myelin subfraction tended to be higher than that in the light myelin subfraction. The acylation of PLP was confirmed by fluorography of immuno-stained cellulose nitrate sheets, clearly establishing that the acylated protein is in fact the oligodendroglial cell- and myelin-specific protein, PLP. Since PLP is acylated in the 9-day-old animal, when little compact myelin is present, it is possible that the acylation of PLP is a prerequisite for the incorporation of this protein into the myelin membrane.     

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.     

Radioimmunoassay for Central Nervous System Myelin-Specific Proteolipid Protein

A double-antibody radioimmunoassay (RIA) has been developed with antisera to purified rat brain myelin proteolipid protein (PLP). The addition of Triton X-100 allowed antibody-antigen interaction and immune precipitation in the presence of sodium dodecyl sulfate (SDS). The RIA will accurately measure 8-80 ng of PLP in buffer or human serum. The RIA is highly specific for myelin PLP and does not cross-react with material in tissues (heart, kidney, muscle, testicle, and intestine) other than the central nervous system. The antibodies to rat myelin PLP cross-react with PLP from bovine brain homogenate or myelin. Myelin PLP was found to account for 55 and 52% of total myelin protein from bovine and rat brain, respectively. Furthermore, there is a higher concentration of PLP in white than in gray matter corresponding to the degree of myelination. Unlike myelin basic protein, myelin PLP was undetectable in both bovine and rat peripheral nervous system.     

Study of the expression of myelin proteolipid protein (lipophilin) using a cloned complementary DNA.

We have prepared a lambda gt10 cDNA library with the mRNA isolated from fetal calf brains which were actively myelinating. Using two oligonucleotides made according to the known amino acid sequence of myelin proteolipid protein (PLP or lipophilin), we have isolated several cDNA clones for this major intrinsic membrane protein of myelin. One of these clones, designated as pLP1, is found to contain 444 bp of coding sequence for the C-terminal half of PLP and 486 bp of 3' untranslated sequence. Using pLP1 as a hybridization probe, we have studied the regulation of PLP at the mRNA level during rat brain development. Our results show that the relative amounts of mRNA for PLP and that for the major extrinsic protein of the myelin membrane, myelin basic protein, increase coordinately during the course of myelination in the brain.     

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.     

An immunologic probe for a defined region of the myelin proteolipid

Antiserum has been prepared against an isolated polypeptide fragment, designated BPS4, which comprises residues 181-211 of the bovine myelin proteolipid. The antiserum recognizes the intact bovine proteolipid protein but not several other polypeptide fragments within the molecule, nor the myelin basic protein, thus demonstrating specificity of the antiserum. In a competitive enzyme-linked immunosorbent assay, both the major proteolipid and the DM 20 bands observed on sodium dodecyl sulfate-polyacrylamide gels reacted equally well with the antiserum, indicating that the BPS4 segment is present in both molecular species. The rat myelin proteolipid protein cross-reacted with antiserum against the intact bovine protein but showed minimal cross-reactivity with the antiserum against the bovine BPS4 fragment. This was demonstrated in parallel experiments using three types of preparations, namely, sodium dodecyl sulfate-solubilized myelin, delipidated myelin, and isolated proteolipid apoprotein. The difference between the bovine and rat proteins, which presumably reflects amino acid sequence differences, is thus detectable by the antiserum against the polypeptide fragment but not by the antiserum against the intact protein. Isolated bovine myelin membranes did not bind the antiserum in the absence of detergent or without delipidation. On the other hand, in vesicles reconstituted with the intact bovine apoprotein, the BPS4 segment was oriented on the exterior face of the liposome where it was capable of binding antibody and was susceptible to Pronase digestion.     

Nucleotide sequences of two mRNAs for rat brain myelin proteolipid protein

The 3200 and 1600 nucleotide mRNAs encoding rat brain proteolipid protein (PLP), the major protein component of central nervous system myelin, are heterogeneous at their 5' ends, differ in their 3' polyadenylation sites, and are transcribed from a single gene. The mRNAs, which first appear postnatally, encode identical 277 amino acid proteins that are 99% identical to the bovine protein sequence. Thus, PLP has been highly conserved during mammalian evolution. A single amino-terminal methionine is removed post-translationally, indicating that PLP does not require a signal peptide sequence for insertion into the myelin membrane. Mouse and monkey utilize the 3200 but not the 1600 nucleotide mRNA, suggesting that there is no functional necessity for two sizes of rat PLP mRNAs.     

Cell-free acylation of rat brain myelin proteolipid protein and DM-20.

Incubation of rat brain myelin with [3H]palmitic acid in the presence of ATP, CoA and MgCl2 or [14C]-palmitoyl-CoA in a cell-free system resulted in the selective labelling of 'PLP' [proteolipid protein; Folch & Lees (1951) J. Biol. Chem. 191, 807-817] and 'DM-20' [Agrawal, Burton, Fishman, Mitchell & Prensky (1972) J. Neurochem. 19, 2083-2089] which, after polyacrylamide-gel electrophoresis in SDS, were revealed by fluorography. These results provide evidence of the association of fatty acid-CoA ligase and acyltransferase in isolated myelin. Palmitic acid is covalently bound to PLP and DM-20, because 70 and 92% of the radioactivity was removed from proteolipid proteins after treatment with hydroxylamine and methanolic NaOH respectively. Incubation of myelin with [3H]palmitic acid in the absence of ATP, CoA, MgCl2, or all three, decreased incorporation of fatty acid into PLP to 3, 55, 18 and 2% respectively. The cell-free system exhibits specificity with respect to the chain length of the fatty acids, since myristic acid is incorporated into PLP at a lower rate when compared with palmitic and oleic acids. The acylation of PLP is an enzymic reaction, since (1) maximum incorporation of [3H]palmitic acid into PLP occurred at physiological temperatures and decreased with an increase in the temperature; (2) acylation of PLP with [3H]palmitic acid and [14C]palmitoyl-CoA was severely inhibited by SDS (0.05%); and (3) the incorporation of fatty acid and palmitoyl-CoA into PLP was substantially decreased by the process of freezing-thawing and freeze-drying of myelin. We have provided evidence that all of the enzymes required for acylation of PLP and DM-20 are present in isolated rat brain myelin. Acylation of PLP in a cell-free system with fatty acids and palmitoyl-CoA suggests that a presynthesized pool of non-acylated PLP and DM-20 is available for acylation.     

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.     

In vitro acylation of myelin PLP and DM-20 in the quaking mouse brain

Both proteolipid proteins (PLP) and DM-20 were found to be present by the immunoblot technique in myelin isolated from quaking mouse brain; however, the relative concentration of these proteins in myelin from quaking brain was substantially reduced when compared to the control. Brain slices from littermate control and quaking mice were incubated with [³H]palmitic acid to determine the incorporation of fatty acid into myelin proteolipid proteins. Fluorography of gels containing myelin proteins from control and quaking mice brain revealed that both PLP and DM-20 were acylated. The incorporation of [³H]palmitic acid into quaking myelin PLP and DM-20 was reduced by 75% and 20% respectively of those in control brain. The significance of differential acylation of quaking myelin PLP and DM-20 is discussed with respect to availability of non-acylated pools of proteolipid proteins and the activities of acylating enzymes.     

Isolation and identification of proteolipid proteins injimpy mouse brain

Proteolipids were isolated from 20 day old normal andjimpy mouse brain by extraction into chloroform-methanol (21, w/v), delipidated by size-exclusion HPLC, and analyzed by SDS-PAGE, Western blots, amino acid analyses, and N-terminal sequencing. SDS-PAGE showed that a major proteolipid fromjimpy mouse brain had an apparent molecular weight of 23 kDa, intermediate to that of PLP and DM-20 from normal mouse brain. Western blots with 3 different antibodies which recognize residues 200–224, 116–150, and 270–276 respectively recognized immunoreactive material in normal andjimpy PLP. Since antibody reactive with 270–276 did not recognizejimpy PLP, an altered C-terminus of thejimpy protein is suggested. These results demonstrated that a PLP can be partially purified fromjimpy mouse brain. Amino acid analyses failed to show the predicted increase in cysteinyl residues (predicted from cDNA) injimpy PLP. However, whenjimpy brain proteolipids were subjected to N-terminal sequencing, Gly, Leu, Leu, Gly the first four amino acids of PLP were detected. Thus, the partial purification of a proteolipid fromjimpy mouse brain, whose characteristics (apparent molecular weight, immunoreactivity, N-terminal sequence and relative net charge) strongly suggested that PLP of altered size is present injimpy mouse brain.Abbreviations BCIP 5-bromo-4-chloro-3-indolyl phosphate toluidine salt - MBP myelin basic protein - NBT -nitro blue tetrazolium chloride - PITC phenylisothiocyanate - PLP myelin proteolipid protein - PVDF polyvinylidene difluoride - SDS-PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis Special issue dedicated to Dr. Marjorie B. Lees.     

Conserved Fatty Acid Composition of Proteolipid Protein During Brain Development and in Myelin Subfractions

Myelin proteolipid protein (PLP) is modified after translation by the attachment of long-chain fatty acids to several cysteine residues. In this study, the amount and pattern of fatty acids covalently bound to rat PLP were determined during brain development and in myelin subfractions. For this purpose, PLP was isolated by gel-filtration chromatography in organic solvents, subjected to alkaline methanolysis, and the released fatty acid methyl esters were analyzed by gas-liquid chromatography. At all ages examined, PLP had the same amount of covalently-bound fatty acids (3–4% w/w) and palmitate, oleate and stearate were always the major acyl chains. In contrast to myelin lipids, the fatty acid composition of PLP showed only minor changes between 15-days and 90-days of age. The amount and pattern of fatty acids bound to PLP prepared from three myelin subfractions were also indistinguishable. The conservation of a characteristic PLP-fatty acid make-up during brain development and in various myelin compartments suggests that this post-translational modification is essential for the normal functioning of the protein.     

Immunoblot Identification of 13.5 Kilodalton Myelin Basic Protein in Goldfish Brain Myelin

Myelin isolated from goldfish brain shows a multilamellar structure with a major dense line and two intraperiod lines. Sodium dodecyl sulfate gel electrophoresis revealed that the protein profile of goldfish brain myelin is distinctly different from that of rat brain myelin. No protein migrating to the position of proteolipid protein or DM-20 was seen in goldfish myelin. Goldfish acclimated to 5 degrees, 15 degrees, and 30 degrees C showed no qualitative differences in myelin proteins. The 13.5 kD protein in goldfish brain myelin and brain homogenate was intensely immunostained with the antiserum to human basic protein by the immunoblot technique. In contrast, none of the proteins of goldfish myelin were immunostained with antiproteolipid protein serum; however, both proteolipid protein and DM-20 of rat brain myelin were immunostained. The significance of the synthesis of myelin proteins by astrocytes in the goldfish brain is discussed.     

Emergence of three myelin proteins in oligodendrocytes cultured without neurons

Oligodendrocytes, the myelin-forming cells of the central nervous system, were cultured from newborn rat brain and optic nerve to allow us to analyze whether two transmembranous myelin proteins, myelin-associated glycoprotein (MAG) and proteolipid protein (PLP), were expressed together with myelin basic protein (MBP) in defined medium with low serum and in the absence of neurons. Using double label immunofluorescence, we investigated when and where these three myelin proteins appeared in cells expressing galactocerebroside (GC), a specific marker for the oligodendrocyte membrane. We found that a proportion of oligodendrocytes derived from brain and optic nerve invariably express MBP, MAG, and PLP about a week after the emergence of GC, which occurs around birth. In brain-derived oligodendrocytes, MBP and MAG first emerge between the fifth and the seventh day after birth, followed by PLP 1 to 2 d later. All three proteins were confined to the cell body at that time, although an extensive network of GC positive processes had already developed. Each protein shows a specific cytoplasmic localization: diffuse for MBP, mostly perinuclear for MAG, and particulate for PLP. Interestingly, MAG, which may be involved in glial-axon interactions, is the first myelin protein detected in the processes at approximately 10 d after birth. MBP and PLP are only seen in these locations after 15 d. All GC-positive cells express the three myelin proteins by day 19. Simultaneously, numerous membrane and myelin whorls accumulate along the oligodendrocyte surface. The sequential emergence, cytoplasmic location, and peak of expression of these three myelin proteins in vitro follow a pattern similar to that described in vivo and, therefore, are independent of continuous neuronal influences. Such cultures provide a convenient system to study factors regulating expression of myelin proteins.     

Developmental Study of Proteolipids in Bovine Brain: A Novel Proteolipid and DM-20 Appear Before Proteolipid Protein (PLP) During Myelination

In a developmental study, we have shown that DM-20 is present before proteolipid protein (PLP) in the fetal bovine cerebral hemispheres. When the white matter appears (27-30 weeks of gestation), the amount of DM-20 drastically increases. DM-20 remains the major proteolipid until birth. PLP is detected only 2-4 weeks after the appearance of white matter, that is, more than 4 weeks after the appearance of DM-20. The early appearance of DM-20 at the beginning of myelination raises the question of its particular function. In the adult bovine cerebral hemispheres, PLP is the major proteolipid but DM-20 remains quantitatively important because the PLP/DM-20 ratio ranges from 1.5 to 1.7. In the same developmental study we have, in the fetal cerebral hemispheres, isolated and characterized a novel proteolipid (apparent Mr 20,000), which appears even before DM-20 and is not detected in the adult brain. It is structurally related to PLP and DM-20 because the first 31 N-terminal amino acid residues are the same. However, in immunoblot, it did not react either with the antitridecapeptide 117-129 antiserum of PLP or with the anti-C-terminal hexapeptide antiserum of PLP.     

Simultaneously entry of palmitic acid into proteolipid protein in different myelin subfractions of rat brain

Rats of 20-days of age were injected intracranially with radioactive palmitic acid to study its incorporation into proteolipid protein (PLP) of myelin and myelin subfractions. At short times (120 min), the radioactivity present in PLP was shown to be due to palmitic acid bound to the protein by ester linkages. The specific radioactivity of palmitic acid labeled PLP was identical in all the myelin subfractions except the myelin-like fraction, in which it was lower, suggesting that the entry of the fatty acid into PLP of the different subfractions occurs simultaneously.Experiments using time staggered injections of ¹⁴C- and ³H-labeled palmitic acid also showed that entry of the fatty acid into PLP of the various subfractions was simultaneous. These results seem to indicate that the acylation of PLP occurs in the myelin membrane and that synthesis and transport of this protein are events unrelated to the acylation process.     

Characterization of myelin proteolipid mRNAs in normal and jimpy mice.

A clone specific for the rat myelin proteolipid protein (PLP) was isolated from a cDNA library made in pUC18 from 17-day-old rat brain stem mRNA. This clone corresponded to the carboxyl-terminal third of the PLP-coding region. The clone was used to identify PLP-specific mRNAs in mouse brain and to establish the time course of PLP mRNA expression during mouse brain development. Three PLP-specific mRNAs were seen, approximately 1,500, 2,400, and 3,200 bases in length, of which the largest was the most abundant. During brain development, the maximal period of PLP mRNA expression was from 14 to 25 days of age, and this was a similar time course to that for myelin basic protein mRNA expression. When the jimpy mouse, an X-linked dysmyelination mutant, was studied for PLP mRNA expression, low levels of PLP mRNA were seen which were approximately 5% of wild-type levels at 20 days of age. When jimpy brain RNA was analyzed by Northern blotting, the PLP-specific mRNA was shown to be 100 to 200 bases shorter than the wild-type PLP-specific mRNA. This size difference was seen in the two major PLP mRNAs, and it did not result from a loss of polyadenylation of these mRNAs.     

An electrophoretic analysis of proteolipids from different rat brain subcellular fractions

Proteolipid proteins were extracted from adult rat brain subcellular fractions and purified by chromatography on Sephadex LH-60. Polyacrylamide gel electrophoresis of the delipidized proteins, in the presence or absence of 8 M urea, was carried out with all fractions. The distribution of the various types of proteolipid proteins was studied and their molecular weight calculated by the Ferguson relationship. Several bands of proteolipid proteins were found in the five membrane fractions analyzed. Some of them, such as the 17.5 K and 37 K components were very prominent in mitochondria and synaptosomes. The 30 K component was found in myelin-derived membranes and in microsomes, while the 20 K and 25 K proteolipid proteins were present in all subcellular fractions. The 30 K component (proteolipid protein (PLP)), typical of the purified myelin membranes, showed a similar distribution to that of 2′,3′-cyclic-nucleotide 3′-phosphohydrolase (EC 3.1.4.37) activity, while the other major proteolipid protein present in all subcellular fractions (25 K) did not show such parallelism, indicating that it might not be an exclusive component of myelin. The electrophoretic pattern of microsomal proteolipid proteins did not show the high molecular weight components (aggregates of PLP) which are found in myelin. Furthermore, the 30 K component showed a smaller $\text{Y}{}_0$ value than that of the 30 K found in myelin. Thus the presence of 30 K proteolipid protein in microsomes should not be considered as being due to myelin contamination.     

Isolation and characterization of a cDNA encoding the zebra finch myelin proteolipid protein

A cDNA was isolated from a zebra finch telencephalon cDNA library that encodes the myelin proteolipid protein. The clone was 2874 nucleotides long containing an open reading frame of 831 nucleotides that encoded a 277 amino acid myelin proteolipid protein. The 5-and 3 untranslated regions were 112 and 1931 nucleotides, respectively. In Northern blots the clone hybridized to 3 bands of 3.5, 2.4 and 1.5 Kb in mouse brain RNA, but to only a single band of 3.0 kb in zebra finch brain RNA, suggesting the lack of alternative polyadenylation sites within the 3 untranslated region of the zebra finch PLP mRNAs. There was a small degree of homology between the zebra finch and chicken PLP 5 untranslated regions, but relatively little homology of the 5 untranslated regions of the zebra finch PLP cDNA clone with the homologous regions of PLP cDNAs of many mammalian species. Except for a small stretch of considerable homology, there was little overall homology with the 3 untranslated regions of mammalian PLP mRNAs. Approximately 10% (i.e. 28) of the amino acids in the zebra finch PLP differed from mammalian PLP, with most of these changes located within exon 3. There were 16 amino acid changes between zebra finch and chicken, suggesting that greater sequence variation in PLP structure is tolerated among avian species than among mammalian species.Abbreviations DM20 25 kDa proteolipid protein in myelin - PLP classic 30 kDa myelin proteolipid protein Special issue dedicated to Dr. Marjorie B. Lees.     

Molecular cloning and nucleotide sequence of a cDNA clone coding for rat brain myelin proteolipid

A cDNA library from rat brain was constructed in pBR322 and screened with a 14-mer mixed oligonucleotide probe based on residues 231-235 of bovine proteolipid (PLP). A positive clone was isolated: it contained a 1334-base-pair cDNA insert and was subjected to DNA sequence analysis. The cDNA encoded information for the 276 amino acids of rat PLP. Comparison with bovine PLP sequence showed a complete amino acid sequence homology except for 4 amino acid residues.