Synthesis of myelin basic proteins in the developing mouse brain.

Mice ranging in age from 14 to 39 days were injected intracerebrally with [³H]lysine and rates of incorporation of the isotope were measured into total trichloroacetic acid-precipitable protein and purified myelin basic proteins (MBPs). MBPs were isolated by O-(carboxymethyl)-cellulose chromatography of pH 3 extracts prepared from chloroform-methanol insoluble residues of whole brains. The MBPs prepared in this fashion were further separated by polyacrylamide gel electrophoresis. The gels were sliced and the radioactivity incorporated into each of the two proteins was determined. Analysis of the rates of synthesis of the two basic proteins (using a 2-h labeling period) as a function of age revealed that synthesis of both proteins appeared to peak at about 18 days of age in the mouse. These data suggest that the maximum rate of MBP synthesis coincides with the age of maximal myelin deposition in the mouse. Furthermore the relative rates of synthesis of L and S changed considerably over the developmental period examined. It was observed that the ratio of the rates of synthesis of the small:large basic protein (S/L) increased by approximately 50% between 2 and 4 weeks and declined thereafter. Throughout the developmental period examined, however, the small basic protein appeared to be synthesized at a greater rate than the large protein. The latter data are consistent with previous observations by us and other workers that mouse and rat myelin becomes increasingly enriched in the small relative to the large basic protein with maturation of the membrane.     

Expression of myelin protein genes in the developing brain

The major myelin proteins fall into two classes, the basic proteins and the proteolipid proteins. In mice, five forms of the myelin basic protein (MBP) have been identified with apparent molecular masses of 21.5 kD, 18.5 kD, 17 kD and 14 kD. The 17 kD MBP variant consists of two molecular forms with similar molecular masses but different amino acid sequences. Cell-free translation studies and analyses of MBP cDNAs have shown that each of the MBP variants is encoded by a separate mRNA of approximately 2 000 bp. The five mouse MBP mRNAs appear to be derived by alternative splicing of exons 2, 5, and 6 of the MBP gene. cDNAs encoding four forms of MBP have been isolated from a human fetal spinal cord library. The mRNAs corresponding to these cDNAs are probably derived by alternative splicing of exons 2 and 5 of the human MBP gene. Proteolipid protein (PLP) cDNAs have been isolated from several species and used to establish that the size of the major PLP mRNA is approximately 3 kb. Multiple size classes of the PLP mRNAs exist in mice and rats whereas the 3 kb mRNA is the predominant form in the developing human spinal cord. In normal mice, maximal expression of the PLP gene lags behind that of the MBP gene by several days. Studies on dysmyelinating mutants have determined some of the molecular defects with respect to these two classes of myelin proteins. For example, there is a deletion of a portion of the MBP gene in the shiverer mutant. In the quaking mutant, the expression of both classes of myelin proteins is significantly reduced prior to 3 weeks. However, after 3 weeks, MBP expression approaches normal levels but the newly synthesized protein fails to be incorporated into myelin. In the jimpy mutant, although the expression of both classes of proteins is reduced, PLP expression is most severely affected.     

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.     

Purification and immunohistochemical localization of rat brain myelin proteolipid protein.

Abstract— A homogeneous preparation of proteolipid protein (PLP) from rat brain myelin was isolated by preparative gel electrophoresis in sodium dodecyl sulfate and chemically characterized. The results of amino acid and N-terminal amino acid analyses are reported. The same preparation of myelin PLP was used to produce specific precipitating antibodies. Rabbit and goat antisera to myelin PLP each gave a single precipitin line with purified PLP dissolved in Triton X-100. Under identical conditions, no precipitation was observed with antiserum to myelin basic protein or with control serum. Immunofluorescence localization employing antiserum to PLP demonstrated bright specific fluorescence restricted to the myelin sheaths of axons in all anatomical areas of the rat brain examined. Neuronal cell bodies and their dendrites were completely negative with respect to the presence of proteolipid protein. PLP could not be localized in the cell bodies or fibrous processes in any of the glial elements in the adult rat brain. However, myelin PLP was clearly visible in the cytoplasm and processes of actively myelinating oligodendrocytes in the corpus callosum in the brains of 10-day-old rats.     

Characterization of proteolipid protein fatty acylesterase from rat brain myelin.

A protein fatty acylesterase activity that catalyzes the removal of fatty acid from exogenous proteolipid protein (PLP) has been demonstrated in isolated rat brain myelin. Optimum enzyme activity for the deacylation of PLP was obtained in 0.5% Triton X-100, 1 mM dithiothreitol at pH 7.0 and at 37 degrees C. Other detergents (octyl beta-D-glucoside, Nonidet P-40, and Tween 20) have little or no effect, whereas deacylation was completely abolished by 0.1% sodium dodecyl sulfate or boiling the membrane fraction for 5 min prior to incubation. Under optimal conditions, the rate of deacylation was linear up to 20 min, and the apparent Km for bovine [3H]palmitoyl-PLP was 18 microM. The myelin-associated PLP fatty acylesterase has no apparent requirements for divalent cations (Ca2+, Mg2+, Mn2+), and chelators such as EDTA, [ethylenebis(oxyethylenenitrilo)] tetraacetic acid, and 1,10-phenantroline have little or no effect on enzyme activity. Sulfhydryl and histidine residues are needed for full enzyme activity, whereas the "active serine"-directed inhibitor phenylmethylsulfonyl fluoride has no effect. The myelin-associated protein fatty acylesterase was present throughout brain development and in all myelin subfractions, in agreement with the dynamic metabolism of PLP-bound fatty acids. Enzyme activity was also present in sciatic nerve, brain cortex, and heart whereas liver was devoid of activity. Several esterases, including phospholipase A2, glyoxalase II, and acetylcholinesterase, did not remove fatty acid from PLP. Myelin basic protein, palmitoyl-CoA hydrolase, and myelin-associated nonspecific esterase were also ruled out as the PLP fatty acylesterase. Thus, all data seem to indicate that this enzyme is different from esterases of the lipid metabolism. Finally, stimulation of protein phosphorylation with Ca2+, but not with cyclic-AMP, inhibited PLP deacylation, suggesting that the myelin-associated protein fatty acylesterase activity is regulated by endogenous Ca(2+)-dependent protein kinases.     

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 distribution of myelin basic protein in subcellular fractions of developing Jimpy mouse brain.

Abstract— The amount of myelin basic protein in jimpy mutants and unaffected littermates was measured by radioimmunoassay during the period of most active myelination (11-21 days). This protein was examined in whole brain homogenates and in four subcellular fractions (nuclear, 900 g pellet; heavy membrane, 11,500 g pellet; microsomal, 100,000 g pellet; and cytosol, 100,000g supernatant solution). At all ages examined, the mutants, which have very little myelin in the CNS, had only about 2% the amount of basic protein found in controls. As expected, the amount of myelin basic protein increased 4-fold in the control animals during the developmental period studied. This was not the case in the jimpy mutants, where little increase in the whole brain basic protein was observed. In the jimpy mutants, all of the fractions had significantly less basic protein than control fractions, except the cytosol, where the amounts of basic protein were similar in controls and mutants. These results are discussed with respect to possible mechanisms of myelination and the site of the genetic lesion.     

Myelin basic protein is affected by reduced synthesis of myelin proteolipid protein in the jimpy mouse.

Myelin basic proteins (MBPs) from 6-day-old, 10-day-old, 20-day-old and adult normal mouse brain were compared with those from 20-day-old jimpy (dysmyelinating mutant) mouse brain to determine the effect of reduced levels of proteolipid protein (PLP) on MBPs. Alkaline-urea-gel electrophoresis showed that 6-day-old and 10-day-old normal and jimpy MBPs lacked charge microheterogeneity, since C8 (the least cationic of the components; not be confused with complement component C8) was the only charge isomer present. In contrast, MBPs from 20-day-old and adult normal mouse brain displayed extensive charge microheterogeneity, having at least eight components. A 32 kDa MBP was the major isoform observed on immunoblots of acid-soluble protein from 6-day-old and 10-day-old normal and 20-day-old jimpy mouse brain. There were eight bands present in 20-day-old and adult normal mouse brain. Purified human MBP charge heteromers C1, C2, C3 and C4 reacted strongly with rat 14 kDa MBP antiserum, whereas the reaction with human C8 was weak. This suggested that MBPs from early-myelinating and jimpy mice did not react to MBP antisera because C8 was the major charge isomer in these animals. Purification of MBPs from normal and jimpy brain by alkaline-gel electrophoresis showed that both normal and jimpy MBPs have size heterogeneity when subjected to SDS/PAGE. However, the size isoforms in normal mouse brain (32, 21, 18.5, 17 and 14 kDa) differed from those in jimpy brain (32, 21, 20, 17, 15 and 14 kDa) in both size and relative amounts. Amino acid analyses of MBPs from jimpy brain showed an increase in glutamic acid, alanine and ornithine, and a decrease in histidine, arginine and proline. The changes in glutamic acid, ornithine and arginine are characteristic of the differences observed in human C8 when compared with C1.     

Orientation of myelin proteolipid protein in the oligodendrocyte cell membrane

The orientation of proteins within a cell membrane can often be difficult to determine. A number of models have been proposed for the orientation of the myelin protein, proteolipid protein (PLP), each of which includes exposed domains on the intracellular and extracellular membrane faces. Immunolabeling experiments have localized the C-terminus and the region spanning amino acids 103–116 to the cytoplasmic face of the membrane, but no well characterized antibodies have been available that label extracellular PLP domains. In this report, we describe the generation and characterization of mouse monoclonal antibodies (mAb) against putative extramembrane domains. Three of the mAb, specific for PLP peptides 40–59, 178–191, or 215–232, immunostain live oligodendrocytes, indicating that these regions of the molecule are exposed on the external surface of the cell. In addition, we have used these mAb to study the time-course of incorporation of PLP into the oligodendrocyte membrane. These studies increase our knowledge of the orientation of PLP in the lipid bilayer and are relevant for understanding myelin function. Special issue dedicated to Dr. Marion E. Smith. Marion has filled many roles in my life (M. Lees): She has been a long time colleague, personal friend, meeting roommate, and traveling companion. Even our husbands have become good friends. Further, Marion’s scientific contributions in multiple aspects of neurochemistry have made her a role model for all scientists, and particularly for young women. It should be noted that all of the authors of this paper just happen to be women.     

Pressure-induced dissociation of aggregates of myelin proteolipid protein

Sedimentation velocity and equilibrium experiments have revealed an extremely pressure-sensitive aggregation of myelin proteolipid protein in the presence of Triton X-100, dissociation of the protein aggregate being observed at pressures that are several orders of magnitude lower than those effecting disaggregation of many other proteins. These results highlight the need to employ a range of angular velocities in sedimentation studies of intrinsic membrane protein.     

Ionophoric properties of the proteolipid apoprotein from bovine brain myelin

Ionophoric properties of the Proteolipid Apoprotein have been assayed. This is a highly purified and delipidated intrinsic myelin membrane protein, isolated from bovine brain white matter. The preparation of myelin membrane vesicles or the incorporation of purified protein into Dimiristoylphosphatidylcholine liposomes have been carried out. According to our results, the myelin Proteolipid protein may act as a Na+ and Rb+ (K+) unidirectional ionophoretic channel, which main physiological role could be related to the maintenance of ionic equilibrium of myelin sheath around the axons.     

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.     

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.     

Minireview: Autoimmune responses to myelin proteolipid protein

The authors present a brief historical sketch of the development of our understanding of immune responses to myelin proteolipid protein (PLP) and the acceptance of PLP as a potent antigen in the induction of experimental allergic encephalomyelitis (EAE). The distinct characteristics of the PLP molecule that may contribute to complex immune responses to this protein are reviewed and these responses are compared with those to MBP, both in the pathology of EAE and at the level of the T cell. Recent evidence demonstrating differences between T cell responses to PLP and MBP is reviewed. Finally, the potential contribution of immune responses to PLP in human diseases, particularly mutiple sclerosis (MS), that have been identified to date are then summarized.For the authors to write a review on PLP and its role in EAE without Marjorie is like their sailing a ship without a captain, compass or rudder. This review is largely based on work and ideas generated in Marjorie's laboratory, but it was prepared without her input. Consequently, it lacks her meticulous reflection on the structure of each of its sentences and on the use of each word. Papers written with Marjorie are usually honed to near perfection late into the evening at her kitchen table in Newton, where food, ideas, and warmth abound, and where her very patient and accommodating husband Sidney and a demanding but lovable canine are close at hand. Writing this essay gave the authors a chance to recognize our scientific forebears, to consider where we are at this point and to contemplate our future directions in studying immune responses to PLP. We are, indeed, very grateful and indebted to Marjorie for her generous personal and scientific support, wise guidance, inspiration, strength, energy and, most importantly, friendship. Marjorie, we thank you, you are our role model, and we affectionately anticipate many more years of continued collaboration with you.Abbreviations used in this paper CNS central nervous system - EAE experimental allergic encephalomyelitis - MBP myelin basic protein - MHC major histocompatibility complex - MOG myelin oligodendrocyte cyte glycoprotein - MS multiple sclerosis - PLP myelin proteolipid protein - PNS peripheral nervous system - TcR T cell receptor Special issue dedicated to Dr. Marjorie B. Lees.     

Developmental regulation of myelin basic protein expression in mouse brain

Developmental regulation of myelin basic protein expression in mouse brain has been examined by comparing the myelin basic protein coding potential of mRNA in vitro with the accumulation of myelin basic protein-related polypeptides in vivo. In vitro translation of mRNA isolated from mouse brain generated eight myelin basic protein-related polypeptides with apparent molecular weights of 34K, 30K, 29K, 26K, 21.5K, 18.5K, 17K, and 14K. A similar set of eight myelin basic protein-related polypeptides with corresponding molecular weights was identified in vivo when total brain proteins were analyzed by immunoblotting. Each of the myelin basic protein-related polypeptides shows a characteristic developmental profile in terms of mRNA level and rate of accumulation implying a complex developmental program of myelin basic protein gene expression with regulation and modulation at several different biosynthetic levels.     

Autoacylation of myelin proteolipid protein with acyl coenzyme A

Rat brain myelin proteolipid protein (PLP) is known to contain long chain, covalently bound fatty acids. In the course of characterizing the mechanism of acylation, we found that the isolated PLP, in the absence of any membrane fraction, was esterified after incubation with [3H]palmitoyl coenzyme A (CoA). This observation demonstrated that the protein acts as both an acylating enzyme and an acceptor. Thus, acylation occurs by an autocatalytic process. The possibility of a separate acyltransferase that copurifies with PLP was essentially excluded by adding brain subcellular fractions to the reaction mixtures and by changing the isolation procedure. After deacylation, the protein was acylated at a 4-fold greater rate, suggesting that the original sites were reacylated. The palmitoyl-CoA concentration followed Michaelis kinetics, confirming that spontaneous acylation was not occurring. Pulse-chase experiments indicated that the reaction entails net addition of acyl groups. Although fatty acids are bound via an O-ester linkage, free SH groups are required in the reaction. Denaturation of the protein by sodium dodecyl sulfate or heat inhibits the reaction, whereas cerulenin has little or no effect. PO, the major protein in peripheral nerve myelin, is also an acylated protein, but it was not labeled upon incubation of either peripheral myelin or the isolated protein with [3H]palmitoyl-CoA, demonstrating that it is acylated by a different route. Several synthetic peptides derived from PLP sequences with sites known to be acylated in vivo as well as a series of deacylated PLP tryptic peptides were not labeled, indicating that integrity of the protein is required for acylation. Limited proteolysis and peptide mapping showed that the same sites are acylated in vitro or in vivo, suggesting that the autocatalytic acylation reaction is physiological.     

Acylation of endogenous myelin proteolipid protein with different acyl-CoAs

Fatty acyltransferase activity that catalyzes the transfer of palmitic acid from palmitoyl-CoA to the endogenous myelin proteolipid protein has been demonstrated in isolated rat brain myelin. Optimum enzyme activity for the acylation of proteolipid protein was obtained in 0.1% Triton X-100, 2 mM MgCl2, and 1 mM dithiothreitol at a pH of 7.5 and at 37 degrees C. Other detergents had little or no effect on the reaction whereas acylation was completely abolished by sodium dodecyl sulphate (0.1%). Pulse-chase experiments indicated that the reaction involves the net addition of fatty acid to the protein and not a rapid fatty acid exchange. The rate of acylation was linear up to 30 min, indicating that the concentration of endogenous protein acceptor was constant. Under these conditions and at short time periods, the enzyme activity versus acyl-CoA concentration showed a hyperbolic curve. The apparent Km and Vmax for palmitoyl-CoA was 41 microM and 115 pmol/mg protein/min. Similar values were obtained for stearoyl and oleoyl-CoA, whereas myristoyl-CoA showed a lower specificity for the enzyme. The acyl-CoA specificity was also studied in competition experiments using several saturated and unsaturated fatty acid-CoAs. The product of the reaction was identified as myelin proteolipid protein and the fatty acid was shown to be attached to the protein via an ester linkage. Limited proteolysis and peptide mapping showed that the same sites on the proteolipid protein were acylated when the reaction was carried out in isolated myelin preparations or in brain tissue slices, suggesting physiological importance for the in vitro acylation of endogenous myelin proteolipid protein.     

Spectroscopic analysis of acylated and deacylated myelin proteolipid protein

The effect of covalently bound fatty acid on the conformation of the myelin proteolipid protein has been studied by ultraviolet and intrinsic fluorescence spectroscopy. With dimethyl sulfoxide used as a perturbant, the exposure of Trp and Tyr residues in various mixtures of chloroform-methanol was evaluated by difference spectroscopy of the proteolipid protein (APL) and its chemically deacylated form (d-APL). The fraction of chromophoric groups exposed increased with the proportion of chloroform with 25% of the groups exposed in 1:2 chloroform-methanol and 98% in 3:1 chloroform-methanol. These conformational changes correlate well with changes in intrinsic viscosity. Values for the deacylated form were indistinguishable from those of the acylated protein, suggesting that fatty acids do not affect protein conformation in organic solvents. In water, UV difference spectroscopy indicated that the number of Tyr and Trp groups exposed in both APL and d-APL was relatively small and was independent of the molecular size of the perturbant. However, differences in the environment of the Trp groups in the two forms of the protein could be demonstrated by intrinsic fluorescence. When the protein was excited at 295 nm, the maximum emission wavelength for the acylated protein was 330 nm, whereas it was 335 nm for the deacylated form. Furthermore, the Trp groups in d-APL were more easily quenched by acrylamide than in APL, indicating that they were more exposed, or in a more hydrophilic environment, following deacylation. Protein aggregation appears to be independent of the presence of fatty acids, suggesting that the fluorescence differences between APL and d-APL are related to factors other than aggregation.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vitro synthesis of myelin proteolipid protein from rat brain using a total homogenate system

In vitro synthesis of myelin proteolipid protein (PLP) was explored at different ages using rat brain total homogenates, incubated for 30 min with [³H]glycine. Total proteolipids, extracted from the incubated samples, were separated by SDSPAGE and the radioactivity was measured in the band corresponding to myelin PLP. The incorporation into PLP in relation to the incorporation into brain total proteins increased from 0.04% at 10 days of age to 0.63% at 20 days, and declined slowly thereafter. Time course experiments were carried out using brain homogenates obtained from rats of 20 days of age (i.e. at the period of maximal synthesis of PLP). Labeled PLP molecules were already found at 2.5 min of incubation and the incorporation of the label into this protein, relative to the incorporation into total proteins, did not vary throughout the entire incubation time (30 min). Pulsechase experiments using a similar system and adding cycloheximide at different incubation times showed that the appearance of label into mature PLP was immediately blocked by the inhibitor of protein synthesis. These data suggest that PLP is synthesized as such and not as a pre-protein which is subsequently processed to render mature PLP.