In Vitro Synthesis of the Myelin Basic Proteins: Subcellular Site of Synthesis

Abstract: Brains of 3-week-old C57BL/6J mice were homogenized and fractionated into several subcellular components, each of which was examined for ability to synthesize the myelin basic proteins (MBPs) in vitro. Myelin basic proteins were purified from incubation mixtures by conventional means. That the products of synthesis were the myelin basic proteins was established by solubility at pH 3, co-chromatography with authentic proteins on carboxymethylcellulose and co-migration with standards in two different polyacrylamide gel electrophoretic systems. The fractions examined for their ability to synthesize MBPs were the whole homogenate, postnuclear supernatant, postmitochondrial supernatant, crude mitochondrial pellet, free ribosomes and bound ribosomes. Although there was no requirement for exogenous energy sources for protein synthesis in the whole homogenate, as the homogenate was fractionated an increasing requirement emerged. Most of the label in the MBP preparations from whole homogenate and postnuclear supernatant incubations migrated with the large (L) and small (S) MBPs on gel electrophoresis; however, as the homogenate was subfractionated and incubated, a greater percentage of the label migrated more slowly than L and S on acetic acid-urea gels. To show synthesis of the MBPs the L and S bands were cut out of these gels and rerun on sodium dodecylsulfate gels. Alternatively, MBP preparations were subjected directly to two-dimensional gel electrophoresis and the bands corresponding to L and S were excised and counted. With this method only the whole homogenate, postnuclear supernatant, postmitochondrial supernatant and free ribosomes were observed to synthesize the MBPs in vitro. The "bound" ribosomes were not observed to synthesize significant amounts of the MBPs, incubated either intact or released from the membrane. It was concluded that the free ribosomes are the principal site of synthesis of the myelin basic proteins in the brain.     

IN VITRO SYNTHESIS OF THE MYELIN BASIC PROTEINS IN THE DEVELOPING MOUSE BRAIN: PROPERTIES OF A HOMOGENATE SYSTEM

—An in vitro system using mouse brain homogenates has been developed to study the synthesis of the myelin basic proteins. Incorporation of [³H]leucine into protein in this system did not require additional energy sources. The system was slightly stimulated by glucose and strongly inhibited by puromycin. Myelin basic proteins were isolated from incubation mixtures by conventional techniques of solvent extraction and column chromatography, and finally separated into the large and small components by polyacrylamide gel electrophoresis in an acetic acid-urea system. Gels were stained, sliced, dissolved, and counted, and relative rates of incorporation of label into the two basic proteins were determined at several ages. The ratio of radioactivity incorporated into the small (S) and large (L) basic proteins, over a 30 min incubation period, was found to increase from 0.97 at 10 days to 1.59 at 21 days and decline thereafter. These data generally agree with earlier studies on the in vivo synthesis of the myelin basic proteins in mice. An interesting feature of the time course was that incorporation of [³H]leucine into the purified myelin basic proteins relative to incorporation into total protein in the homogenate increased almost 2-fold during the course of the 30-min incubation. This suggested that post-translational processing of at least one of the two basic proteins was occurring. To examine this possibility further, experiments were conducted in which incorporation was allowed to proceed for 2–5 min, before being inhibited with puromycin; the incubation was then continued for up to 25 min longer. Although total incorporation was inhibited immediately after puromycin addition, label was found to continue to accumulate in the basic proteins to the extent of 30–100% above controls. These data support the notion that the MBPs are synthesized as precursors and then processed to yield authentic myelin basic proteins and that this processing can occur in vitro.     

In vivo phosphorylation of myelin basic proteins: single and double isotope incorporation in developmentally related myelin fractions

The phosphorylation of myelin basic proteins (MBPs) was studied in developing mouse brain. Based on our previous work we postulated that phosphorylation of MBPs takes place prior to their appearance in the myelin compartment as well as within the myelin sheath. To further test this hypothesis we utilized a subfractionation protocol that yields brain fractions enriched in myelin membranes of differing developmental stages. Incorporation of radioactive phosphate into MBPs was studied in each of the subcellular fractions. After 5- and 15-min incubations of isotope in vivo the highest specific radioactivities (SAs) of MBPs were found in the least mature myelin fractions. Incorporation of 32P in MBPs was greater into serine residues than threonine residues in all of the subcellular fractions studied. The relative turnover of MBP phosphates was studied in each of the subcellular myelin fractions using a time-staggered, double isotope methodology. The most rapid equilibration of MBP phosphates with the trichloroacetic acid (TCA)-soluble phosphate pool occurred in the most mature myelin fractions indicating that the highest turnover of MBP phosphates occurs in the most mature myelin fractions. The SAs and turnover rates of each of the four commonly observed mouse MBPs (14, 17, 18.5, and 21.5 kDa) were similar in any particular subfraction demonstrating that the MBP phosphotransferase system(s) acts on each of the MBPs in a similar manner.     

Effects of Altered Thyroid States on Myelinogenesis

Abstract: Myelinogenesis was studied in controls and in rats treated since birth with Methimazole (hypothyroid) or thyroxine (hyperthyroid). The amount of myelin in forebrain and its protein composition were determined between 13 and 40 days of age, the period of most rapid myelin accumulation. Hypothyroid rats had reduced body and brain weights relative to controls and the yield of myelin was reduced on both a per brain and a per milligram brain protein basis. Developmental changes in the protein composition of isolated myelin followed the pattern of control animals (the percentage of total myelin protein present as proteolipid protein, large basic protein, and small basic protein increased, as did the ratio of proteolipid/large basic protein) but were delayed temporally by 1–2 days. Hyperthyroid rats also had reduced body and brain weights. At 13 days myelin accumulation was greater than that of controls, corresponding to an earlier initiation of myelination. At later ages myelin yield was reduced on a per brain basis but not on a per milligram brain protein basis. The developmental pattern of myelin protein composition was accelerated temporally by 1–2 days. Myelination in optic nerve, assayed by proteolipid protein content, also was slightly delayed in hypothyroid animals and somewhat accelerated in hyperthyroid animals. The relative synthesis of myelin proteins (determined as incorporation of intracranially injected [³H]glycine into myelin protein relative to incorporation into whole brain protein), as well as distribution of radioactivity among individual myelin proteins, was determined. The results supported the conclusion of the myelin protein accumulation study; hypothyroidism retards the developmental program for myelinogenesis, whereas in the hyperthyroid state myelin synthesis is initiated earlier but is also terminated earlier.     

Synthesis of the myelin proteolipid protein in the developing mouse brain

Mice ranging in age from 16 to 44 days were injected intracerebrally with ³H-leucine, and incorporation into total brain proteolipids and the myelin proteolipid protein was measured. All proteolipids were isolated from whole brain by ether precipitation and separated into their individual components by SDS polyacrylamide gel electrophoresis. Two major proteolipids with apparent molecular weights of 20,700 and 25,400 were observed in these preparations, and their proportion increased over the developmental period examined. A Ferguson plot analysis comparing these proteins with those of isolated myelin showed that the 25,400-dalton proteolipid component from whole brain was the myelin proteolipid protein. Rates of incorporation of ³H-leucine into total brain proteolipids peaked at 22 days of age. Synthesis of the myelin proteolipid protein increased rapidly to a maximum value at 22 days and decreased rather slowly until at 44 days it was about 83% of its maximum rate of synthesis. The data indicate that the developmental pattern of synthesis of the myelin proteolipid protein is unlike that of the myelin basic proteins. Synthesis of the major myelin proteins is developmentally asynchronous in that peak synthesis of the myelin proteolipid appears to occur several days later than the basic proteins. In addition, it maintains its maximum rate of synthesis over a longer period of time than do the basic proteins.     

Synthesis and incorporation of myelin polypeptides into CNS myelin

The distribution of newly synthesized proteolipid protein (PLP, 23 kdaltons) and myelin basic proteins (MBPs, 14-21.5 kdaltons) was determined in microsomal and myelin fractions prepared from the brainstems o1 10-30 d-old rats sacrificed at different times after an intracranial injection of 35S-methionine. Labeled MBPs were found in the myelin fraction 2 min after the injection, whereas PLP appeared first in the rough microsomal fraction and only after a lag of 30 min in the myelin fraction. Cell-free translation experiments using purified mRNAs demonstrated that PLP and MBPs are synthesized in bound and free polysomes, respectively. A mechanism involving the cotranslational insertion into the ER membrane and subsequent passage of the polypeptides through the Golgi apparatus is consistent with the lag observed in the appearance of the in vivo-labeled PLP in the myelin membrane. Newly synthesized PLP and MBPs are not proteolytically processed, because the primary translation products synthesized in vitro had the same electrophoretic mobility and N-terminal amino acid sequence as the mature PLP and MBP polypeptides. It was found that crude myelin fractions are highly enriched in mRNAs coding for the MBPs but not in mRNA coding for PLP. This suggests that whereas the bound polysomes synthesizing PLP are largely confined to the cell body, free polysomes synthesizing MBPs are concentrated in oligodendrocyte processes involved in myelination, which explains the immediate incorporation of MBPs into the developing myelin sheath.     

Developmental Expression of the Myelin Proteolipid Protein and Basic Protein mRNAs in Normal and Dysmyelinating Mutant Mice

Expression of the myelin proteolipid protein (PLP) was examined in the nuclei and polysomes of 12-27-day-old quaking, jimpy, and shiverer mouse brains and in 2-27-day-old normal brains and compared with expression of the myelin basic proteins (MBPs). Northern blots showed the presence of multiple mouse PLP RNAs, the developmental expression of which coincided with myelination. Two major mouse PLP RNAs, 3.5 and 2.6 kilobases in length, were observed in both cytoplasmic polyribosomes and nuclei, and, in addition, a larger 4.6-kilobase PLP RNA was observed in nuclei. Quantitative measurements with slot blot analyses showed that the levels of PLP and MBP RNAs peaked simultaneously at 18 days in nuclei but that maximal levels of PLP RNA lagged behind MBP RNA by several days in the polysomes. The developmental expression of both major classes of myelin protein mRNAs was affected in all three mutants. In shiverer brains, the levels of PLP mRNA in polysomes and nuclei were only 30-55% of control levels after 15 days. Thus, the deletion of a portion of the MBP gene appeared to have a major effect on the expression of the PLP gene in this mutant. In jimpy mice, where the mutation has been shown to involve the PLP gene, expression of MBP mRNA was also severely reduced, to less than 25% of control values. In quaking brains, the expression of each gene followed its own developmental course, different from each other and different from the normal mouse. The extent to which the expression of PLP and MBP was affected by the quaking mutation depended on the age at which it was examined.     

Expression of Myelin Proteolipid Protein and Basic Protein in Normal and Dysmyelinating Mutant Mice

Expression of myelin proteins was studied in the brains of 21-day-old normal mice and three dysmyelinating mutants-jimpy, quaking, and shiverer. Total brain polyribosomes and poly(A)+ mRNA were translated in two cell-free systems and the levels of synthesis of the myelin basic proteins (MBPs) and proteolipid protein (PLP) were determined. Synthesis of the MBPs in quaking homozygotes was at or above normal levels but PLP synthesis was significantly reduced to approximately 15% of control values, indicating independent effects on the expression of these proteins in this mutant. Immunoblot analysis of 21-day-old quaking brain homogenates showed a reduction in the steady-state levels of MBPs and PLP, suggesting a failure of newly synthesized MBPs to be incorporated into a stable membrane structure such as myelin. In the shiverer mutant very little synthesis of MBPs was observed, whereas greater synthesis of PLP occurred (approximately 50% of control). Almost no MBP, and low levels of PLP, were detected in the immunoblots, suggesting the possibility of a partial failure of PLP to be assembled into myelin in shiverer. In the jimpy mutant, low levels of MBP synthesis were observed in vitro (approximately 26% of controls) and very little synthesis of PLP was evident. The immunoblots of 21-day jimpy brain homogenates revealed no appreciable steady-state levels of PLP or MBP, again indicating that most newly synthesized MBPs were not incorporated into a stable membrane structure in this mutant. In sum, the data show that in the three cases examined, the mutation appears to affect the expression of the MBPs and PLP independently. Furthermore, regardless of their absolute levels of synthesis these proteins may or may not be assembled into myelin.     

Myelin basic proteins in myelin subfractions from normal and quaking mice.

The relative proportions of four myelin basic proteins (preL, L, preS,S) were determined in myelin subfractions prepared from the forebrains of quaking and littermate control mice. The distribution pattern of each protein was similar in both mutant and control fractions. The S component was the only basic protein present in low amounts in myelin from the mutant.     

In vivo phosphorylation of myelin basic proteins: age-related differences in 32P incorporation

Myelin basic proteins (MBPs) are phosphoproteins of central and peripheral nervous system myelin. We studied the phosphorylation of mouse MBPs in vivo at three different stages of development (12, 30, and 50 days) and found age-related differences in the incorporation of 32P into MBPs. At all ages studied, significant amounts of 32P were found in the MBPs as early as 1 min after intracranial injection of isotope. Incorporation of radioactive phosphate into MBPs proceeded rapidly and the resultant specific radioactivity (SA) of 32P-labeled MBPs appeared to be related to the SA of the acid-soluble phosphate pool of myelin. Changes in the SA of the myelin acid-soluble phosphate pool were observed in a 30 min time course of labeling in vivo in 50-day mice. Coincident changes were observed in the SA of the MBPs. Similar but less pronounced changes were seen in the SA of the polyphosphoinositides (PPIs) indicating that the turnover of the PPI phosphate groups is slower than the MBP phosphates or that the PPI phosphates are drawn from additional or different pools than the MBP phosphates. The phosphorylation of MBPs in developmentally related myelin fractions is investigated in a comparison paper (J. B. Ulmer and P. E. Braun (1986) Dev. Biol. 117, 502-510).     

Characterization of Basic Proteins from Goldfish Myelin

Abstract: Myelin basic protein (MBP) from common goldfish ( Carassius auratus ) myelin was extracted with dilute mineral acid. Immunological cross-reactivity of the goldfish MBP, with polyclonal antisera raised against bovine MBP, suggested that the goldfish protein has epitopes for these antibodies. It also reacted with a monoclonal antibody specific for a seven amino acid epitope (130–137) conserved in the MBP of most mammalian species. To characterize the charge heterogeneity of this protein, we iodinated the protein with ¹²⁵I and chromatographed it on a carboxymethyl cellulose-52 column together with a nonlabeled acid soluble fraction prepared from human white matter as a carrier protein. All of the goldfish protein was recovered in the unbound fraction, demonstrating that it was less cationic than the carrier protein (human MBP). We have also examined the urea alkaline gel profile of the goldfish MBP together with the human C-1, C-2, C-3, C-4, and C-8 components. The results from these experiments indicated that this MBP extracted from goldfish brain myelin lacked the microhet-erogeneity that is associated with MBPs from higher vertebrates. The MBPs from goldfish myelin were separated into their isoforms by reversed-phase HPLC. Amino acid compositions were determined for both the 17- and 14-kDa goldfish proteins. Amino acid analysis revealed similarities with the compositions of other MBPs; however, the serine content in both the 17- and 14-kDa proteins was higher than that of the human C-1, the mouse C-1 protein, and the shark proteins. The HPLC-purified 14-kDa goldfish protein was chemically cleaved with CNBr for partial sequence analysis. Even from the limited sequence obtained, the sequence ATAST was found in goldfish, which is also present in human, rabbit, and guinea pig MBPs.     

Protein Composition of PNS Myelin: Developmental Comparison of Control and Quaking Mice

Protein compositions were determined for sciatic nerve myelin isolated from young and adult control and quaking (Qk) mice. Age-related changes in the relative amounts of large (Pl) and small (Pr) basic proteins were found. In control animals, the ratio Pr/Pl increased with age, a change similar to that observed for the large (Bl) and small (Bs) CNS myelin basic proteins of adult mice. Pr/Pl also increased with age in the Qk mouse sciatic nerve, but only to the point that the value in the adult Qk mouse was similar to that observed for young control animals, a situation reminiscent of the effect of the Qk mutation on CNS basic proteins. Thus, our data suggest that the Qk mutation has a similar effect on peripheral nervous system (PNS) and CNS basic proteins. Our findings are consistent with recent electrophoretic and immunochemical data showing that PNS and CNS myelin basic proteins in rodents are analogous, and they suggest that the genetic program controlling basic protein expression is common to oligodendroglia and Schwann cells.     

Studies on Subcellular Fractions Which Are Involved in Myelin Assembly: Labeling of Myelin Proteins by a Double Radioisotope Approach Indicates Developmental Relationships

The question of developmental relationships amongst myelin-related membranes in subfractions of myelinating mouse brain (15 days) was investigated by a time-staggered double isotope protocol using [3H]leucine and [14C]leucine. Preliminary results are interpreted and discussed in the context of a mathematical conceptualization of pulse-labeling kinetic analyses of myelin proteins in subcellular membrane compartments. Differences in ratio of the two leucine labels among proteins of myelin-containing subfractions are interpreted as confirming metabolic differences relating to various stages of development rather than precursor-product relationships. The incorporation into myelin of 14K, 17K, and 18.5K basic proteins (MBPs) occurs with relatively short delay times, following their synthesis (less than 5 min), and seems to occur simultaneously into all compartments. The 21.5K MBP and the proteolipid protein, on the other hand, require 10-14 min and 14-20 min, respectively. A scheme is presented to illustrate the probable assignment of subfractions to various myelin "compartments" during myelination, and to serve as a working hypothesis for studies on precursor-product relationships.     

Calcium-Stimulated Proteolysis in Myelin: Evidence for a Ca2+-Activated Neutral Proteinase Associated with Purified Myelin of Rat CNS

Incubation of myelin purified from rat spinal cord with CaCl2 (1-5 mM) in 10-50 mM Tris-HCl buffer at pH 7.6 containing 2 mM dithiothreitol resulted in the loss of both the large and small myelin basic proteins (MBPs), whereas incubation of myelin with Triton X-100 (0.25-0.5%) and 5 mM EGTA in the absence of calcium produced preferential extensive loss of proteolipid protein (PLP) relative to MBP. Inclusion of CaCl2 but not EGTA in the medium containing Triton X-100 enhanced degradation of both PLP and MBPs. The Ca2+-activated neutral proteinase (CANP) activity is inhibited by EGTA (5 mM) and partially inhibited by leupeptin and/or E-64c. CANP is active at pH 5.5-9.0, with the optimum at 7-8. The threshold of Ca2+ activation is approximately 100 microM. The 150K neurofilament protein (NFP) was progressively degraded when incubated with purified myelin in the presence of Ca2+. These results indicate that purified myelin is associated with and/or contains a CANP whose substrates include MBP, PLP, and 150K NFP. The degradation of PLP (trypsin-resistant) in the presence of detergent suggests either release of enzyme from membrane and/or structural alteration in the protein molecule rendering it accessible to proteolysis. The myelin-associated CANP may be important not only in the turnover of myelin proteins but also in myelin breakdown in brain diseases.     

Partial deficiencies in the myelin proteins of developing mice heterozygous for the shiverer mutation

The central nervous system of the shiverer mouse is known to be severely deficient in myelin. Animals heterozygous for this autosomal-recessive mutation were crossed, and the myelin proteins were examined in the brains and spinal cords of shiverers and unaffected littermates among the offspring. In the brains and spinal cords of nine of the 14 unaffected littermates examined, the quantities of the myelin basic and proteolipid proteins were lower than normal. Furthermore, in the brains of heterozygotes 33 to ～ 150 days old, the myelin basic and proteolipid proteins were reduced in amount, compared to wild-type controls; the myelin basic protein was also present in subnormal amounts in the spinal cords from heterozygous animals at the ages of 17 to 150 days. More severe reductions in the quantities of the myelin proteins were observed in central nervous system tissue from homozygous shiverer mice, and the quantity of the myelin proteolipid protein in the central nervous system of the shiverer mouse, expressed as a ratio to the control value at each age, underwent a developmental decline. In heterozygotes, as well as shiverers, the peripheral nerves were also deficient in the P₁ and P_r proteins, which are the same as the basic proteins in rodent central nervous system myelin. The findings regarding heterozygotes suggest that the defective primary gene product in the shiverer mouse could be the myelin basic protein itself or a protein required for a rate-limiting step in the processing of the myelin basic protein.     

Accumulation of the four myelin basic proteins in mouse brain during development.

Myelin was isolated from the brains of mice 15, 20, 30, and 60 days after birth. The total amount of basic protein present in the isolated myelin was determined by radioimmunoassay. The 4 myelin basic proteins, with molecular weights of 21,500, 18,500, 17,000 and 14,000, were separated by sodium dodecyl sulfate polyacrylamide gel electrophoresis and their relative amounts were determined densitometrically. The absolute amount of each of the basic proteins was calculated from its relative amount on the gel and from the total amount of myelin basic protein in the sample as determined by radioimmunoassay. The results show that between 10 and 30 days after birth each protein accumulates at a characteristic rate so that the molar ratios among the 4 basic proteins are (in descending order according to their molecular weights) 1:5:2:10 during this period. Between 30 and 60 days after birth the 14 K and 18.5 K proteins continue to accumulate at reduced rates while the 21.5 K and 17 K proteins begin to disappear from the myelin membrane; 60 days after birth the molar ratios among the 4 basic proteins are 1:10:3.5:35. These developmental patterns of accumulation are discussed in relation to the possible role of each of the 4 myelin basic proteins in myelination.     

Synthesis of secretory proteins in developing mouse yolk sac

Synthesis of secretory proteins in the developing mouse visceral yolk sac was studied. Newly synthesized proteins were labeled with [³⁵S]methionine and characterized by two-dimensional gel electrophoresis. A large increase in the relative rate of synthesis of a small number of proteins occurred between Days 9.5 and 15.5 of development. These proteins were the predominant proteins synthesized and secreted by the yolk sac throughout this period of gestation. Two of these proteins were identified as α-fetoprotein and transferrin by specific immunoprecipitation. α-Fetoprotein synthesis increased from about 3% of the total protein synthesis at Day 9.5 to about 26% at Day 15.5 after which it declined slightly. The relative rate of transferrin synthesis had a similar developmental pattern, reaching the highest level (5%) at Day 15.5, but declined more rapidly than α-fetoprotein synthesis. Quantitatively, these two proteins represented about 60% of the total secreted protein. Gestational changes in the content of α-fetoprotein messenger RNA were determined by hybridization analysis using α-fetoprotein complementary DNA probe. The percentage of α-fetoprotein messenger RNA in total yolk sac RNA increased about ninefold from Day 9.5 to Day 14.5. This increase correlated well with the increase in the relative rate of α-fetoprotein synthesis during the identical period. This study suggests that after Day 9.5 the yolk sac is completing a differentiation process which is characterized by the preferential expression of a small group of secretory protein genes.     

Morphological and biochemical characterization of light and heavy myelin isolated from developing rat brain

Myelin from developing rat brains was separated on a discontinuous sucrose gradient into subfractions of two different densities, i.e. light and heavy myelin. Electron photomicrographs showed that heavy myelin consisted primarily of large compacted multilamellar structures with a distinct intraperiod line characteristic of myelin in situ. Light myelin, on the other hand, was composed of small vesicles having a unilamellar structure. Similar to whole myelin, both membrane subfractions were highly enriched in 2′,3′-cyclic nucleotide-3′-phosphohydrolase. The specific activity of the enzyme, however, showed no developmental trend. Both subfractions contained all of the four major proteins characteristic of the whole myelin membrane. There were, however, quantitative differences in the relative distribution of these proteins between light and heavy myelin. Basic protein accounted for 55 % and proteolipid protein for 46 % of the total myelin proteins of light and heavy myelin, respectively. DM-20 (Agrawal, H. C., Burton, R. M., Fishman, M. A., Mitchell, R. F. and Prensky, A. L. (1972) J. Neurochem. 19, 2083–2089) exhibited a developmental “switch” between light and heavy myelin. Light myelin appeared to contain more DM-20 in 15- to 20-day-old rat brain, whereas the concentration of this protein was higher in heavy myelin at subsequent ages studied.     

KINETICS OF ENTRY OF PROTEINS INTO THE MYELIN MEMBRANE1

Brain slices were prepared from 17-day old rats, and incubated with [³H]glycine or [³H]-leucine to label proteins. Myelin was isolated from the slices, and the proteins were separated by discontinuous gel electrophoresis in buffers containing sodium dodecyl sulfate. Radioactive basic and Wolfgram proteins appeared in myelin at similar initial rates, and their entry was nearly linear between 15 and 120 min with no detectable lag. Radioactive proteolipid protein appeared in myelin at one-fourth the rate of the basic and Wolfgram proteins between 0 and 30 min, then entered at a rate comparable to the other proteins between 45 and 120 min. When cycloheximide (0.2 mM) or puromycin (1.0 mM) was added, appearance of newly labeled basic and Wolfgram proteins in myelin stopped while proteolipid protein continued to appear in myelin at a normal rate for at least 30 min. Chase experiments with unlabeled glycine had similar effects. These results indicate the existence of a previously synthesized precursor pool of proteolipid protein with a 30-min interval between synthesis of proteolipid protein and its appearance in myelin. Incorporation of [³H]fucose into glycoprotein of the myelin sheath was studied, as was inhibition of incorporation of radioactivity by the use of either cycloheximide, or dilution with unlabeled fucose. The results indicated fucosylation of a sizable pool of presynthesized protein and a delay of 30 min between fucosylation of these polypeptides and their subsequent appearance in myelin as glycoproteins.     

Morphological and biochemical characterization of light and heavy myelin isolated from developing rat brain.

Myelin from developing rat brains was separated on a discontinuous sucrose gradient into subfractions of two different densities, i.e. light and heavy myelin. Electron photomicrographs showed that heavy myelin consisted primarily of large compacted multilamellar structures with a distinct intraperiod line characteristic of myelin in situ. Light myelin, on the other hand, was composed of small vesicles having a unilamellar structure. Similar to whole myelin, both membrane subfractions were highly enriched in 2',3'-cyclic nucleotide-3'-phosphohydrolase. The specific activity of the enzyme, however, showed no developmental trend. Both subfractions contained all the four major proteins characteristic of the whole myelin membrane. There were, however, quantitative differences in the relative distribution of these proteins between light and heavy myelin. Basic protein accounted for 55% and proteolipid protein for 46% of the total myelin proteins of light and heavy myelin, respectively. DM-20 (Agrawal, H.C., Burton, R. M., Fishman, M.A., Mitchell, R.F. and Prensky, A.L. (1972) J. Neurochem. 19, 2083-2089) exhibited a developmental "switch" between light and heavy myelin. Light myelin appeared to contain more DM-20 in 15- to 20-day-old rat brain, whereas the concentration of this protein was higher in heavy myelin at subsequent ages studied.