CHANGES IN THE PROTEIN COMPOSITION OF MOUSE BRAIN MYELIN DURING DEVELOPMENT

Abstract— Myelin was isolated from the brains of mice at various ages by a procedure involving a final purification on a continuous CsCl gradient. Myelin protein accumulated throughout development, increasing from 0.25 mg of protein/brain at 8 days of postnatal age to 3.5 mg of protein/brain at 300 days, although the rate of accumulation was greatest at about 21 days of age. Quantitative studies of the protein composition of these samples were carried out, utilizing discontinuous polyacrylamide gel electrophoresis in buffers containing sodium lauryl sulphate. Mouse brain myelin, contained (in order of increasing molecular weight) two basic proteins, an uncharacterized doublet, proteolipid protein, and a group of high molecular weight proteins. There were marked changes in the quantitative distribution of these proteins with increasing postnatal age. The basic protein fraction of total myelin protein increased from about 18 per cent at 8 days to 30 per cent at 300 days of age. Proteolipid protein increased even more dramatically, from 7 to 27 per cent in the same time interval. These chemical studies were correlated with ultrastructural investigations, both of the developing myelin sheath in situ and the isolated myelin obtained from mice of various ages. A hypothesis, relating the observed changes in protein composition of myelin during development to its mode of formation, is developed. Another subcellular fraction, separated from myelin, by virtue of its greater density in a CsCl gradient, was also studied. It was a vesicular, membranous fraction present at a level of 0.35 mg of protein/brain at all ages and was related to myelin in terms of protein composition.     

MEMBRANE PROTEINS OF RAT BRAIN: COMPOSITIONAL CHANGES DURING POSTNATAL DEVELOPMENT

Abstract— Membrane fractions from forebrain of rat were isolated at ages ranging from 5 to 93 days. Among these fractions were total membranes, three fractions isolated by density gradient centrifugation, and three subfractions which consisted of purified myelin and of two supernatant fractions. All membrane fractions showed an increase in protein content during the first postnatal month; however, only the myelin fraction and one of its supernatant fractions showed a prolonged accumulation. Myelin protein increased continually from 0.17 mg/g brain at 15 days to 8.3 mg/g brain at 93 days.
All fractions were analysed for protein composition by sodium dodecyl sulphate polyacrylamide gel electrophoresis. Characteristic changes in protein composition were noted during postnatal development, most of which were pronounced up to the age of 20 days. Among others was a decrease in histones as compared to other proteins, with a concomitant shift in preponderance from the slow- to the fast-migrating histone band. In parallel, other proteins of high molecular weight became more prominent. No myelin could be isolated at 5 and 10 days. The deposition of myelin proteins was parallelled by the appearance of the Wolfgram protein which points to a close correlation of the Wolfgram protein to the process of myelination.     

Appearance of newly synthesized protein in myelin of young rats.

Abstract— Seventeen-day-old rats were injected intracranially with [³H]leucine, then sacrificed between 1 and 24 h. Myelin was prepared from the brains on discontinuous sucrose gradients and the proteins were separated by discontinuous gel electrophoresis in buffers containing sodium dodecyl sulphate. Proteins were stained with acid Fast Green and the distribution was quantitated by densitometry. The gels were then sliced and the radioactivity in each slice was determined. Between 1 and 24 h, the radioactivity in proteolipid protein increased from 18% to 37% of the total radioactivity in the proteins of isolated myelin. During this same period, the per cent distribution of radioactivity in basic and Wolfgram proteins remained constant while that in the remaining high molecular weight proteins decreased. Similar results were also obtained with [³H]glycine as a precursor. The relative specific activity of all of the myelin proteins increased between 1 and 6 h, then remained constant between 6 and 24 h. At 1 h, proteolipid protein reached only 25% of its maximal (6 h) relative specific radioactivity, while the other two proteins reached 50% of maximum. These results indicate a lag in the appearance of labelled amino acids in proteolipid protein relative to the other myelin proteins.     

GLIAL VERSUS NEURONAL ORIGIN OF MYELIN PROTEINS AND GLYCOPROTEINS STUDIED BY COMBINED INTRAOCULAR AND INTRACRANIAL LABELLING

Abstract— —The contribution of axonal transport to the production of myelin proteins and glycoproteins was investigated using the double labelling technique of combined intraocular and intracerebral injections in the same animal. Myelin and an axolemma-enriched fraction were isolated from pooled optic nerves, chiasma and optic tracts. Separation by gel electrophoresis showed that typical myelin proteins and glycoproteins were only significantly labelled by intracerebral injection. Intraocular injection labelled high molecular weight proteins other than the major Wolfgram protein and the major myelin glycoprotein. Fifteen days after intraocular injection the label was concentrated in a high molecular weight protein which migrated slightly more slowly than the major Wolfgram protein. The pattern of proteins and glycoproteins in myelin labelled by intraocular injection was very similar to that obtained in the axolemma-enriched fraction by the same route. These results indicate that neuronal metabolism and axonal transport do not contribute significantly to the synthesis of specific myelin proteins and glycoproteins, but suggest that the components of myelin fractions which are labelled by intraocular injection are contaminants of axolemmal origin. One of these glycoproteins may prove a useful marker of axolemma membranes.     

MYELIN SYNTHESIS IN VITRO: A COMPARATIVE STUDY OF CENTRAL AND PERIPHERAL NERVOUS TISSUE

Abstract— Brain, spinal cord and sciatic nerve from rats at different ages were incubated for 2 h in a medium containing [¹⁴C]acetate and [¹⁴C]leucine as the precursors for synthesis of lipids and proteins. Myelin was purified from the incubated tissues and the specific and total radioactivites of myelin lipids and protein were determined. The uptake of radioactive precursors decreased with increasing age up to 6 months of postnatal age, the decrease following the same pattern for the three types of myelin. After age 6 months the uptake of the protein and lipid precursors reached a plateau that persisted up to 18 months, the oldest postnatal age studied. The amount of myelin isolated and the total myelin lipids extracted from both the central and peripheral nervous systems increased continuously from age 25 days to 18 months after birth. Consequently we suggest that myelination is a process that continues during the whole life of the rat.
The metabolic activity of peripheral nerve myelin was higher than myelin from the CNS at all ages studied. Although myelination in the sciatic nerve begins before that in brain and spinal cord, the three types of myelin apparently reach maturity at the same age. Lecithin exhibited the highest metabolic activity of the individual myelin lipids at all ages in both the central and peripheral nervous system. The metabolic activity of cholesterol in myelin from the 25-day-old rats was similar to that of lecithin but decreased to very low levels in myelin from the 18-month-old rats.     

Maternal deficiency of protein or protein and calories during lactation: effect upon CNS myelin subfraction formation in rat offspring.

The present study has examined the effects of maternal protein and protein-calorie deficiency during lactation on the development of CNS myelin subfractions in rat offspring. The offspring of both the protein and protein-calorie deficient rats had decreased brain and body weights, as well as delayed CNS myelination. Delayed active CNS myelination was demonstrated by the fact that 53-day-old nutritionally stressed pups incorporated significantly more [³H]leucine and [¹⁴C]glucose into all myelin subfractions than age-matched controls. Delayed myelination was also supported by the tremendous accretion of myelin proteins in the nutritionally deprived pups between 25 and 53 days of age. Despite the delayed active synthesis of myelin, the myelin deficit persisted in the offspring of protein deficient rats. These offspring had a deficiency of light + medium myelin throughout the study. At 17 days, both groups of nutritionally stressed rats had an excess of the high molecular weight proteins in heavy myelin. Heavy myelin from 17 day offspring of protein-calorie deficient rats had a deficiency of basic proteins, while that from the offspring of protein deficient rats had a deficiency of proteolipid protein. The protein composition of all myelin subfractions was normal at 53 days.     

METABOLIC ACTIVITY OF CNS PROTEINS IN RATS AND MONKEYS WITH EXPERIMENTAL ALLERGIC ENCEPHALOMYELITIS (EAE)

—The metabolic activity of proteins from myelin and non-myelin fractions of slices of lesions in monkey brains and in spinal cords of Lewis rats with acute experimental allergic encephalomyelitis was investigated using [1-¹⁴C]leucine as a protein precursor. The uptake in vitro of [1-¹⁴C]leucine into the monkey EAE lesions was greatly increased in both the myelin and non-myelin fractions. Similar findings were made in spinal cord slices of the EAE rat with an average specific activity 341 per cent of control measured in proteins of purified myelin and 415 per cent of control in the non-myelin protein. The increased uptake appeared with the onset of paralytic symptoms 10–14 days after injection. The increased uptake did not appear to be a result of an increased amino acid pool size as measured with uniformly labelled l -leucine, valine, arginine and phenylalanine. The increase in specific activity of the myelin protein of the EAE rats was shown to be associated with the peaks characteristic of myelin protein when separated on polyacrylamide gels and the serial slices counted. Most of the radioactivity of both the control and EAE myelin protein migrated with the high molecular weight fraction, and the largest increase in radioactivity in myelin protein appeared in this fraction. Some increase in specific activity was also found in the basic and proteolipid proteins. Four different guinea-pig antigens were used to induce EAE: whole spinal cord, purified basic protein, purified myelin and basic protein + cerebroside. All caused paralytic symptoms and greatly increased incorporation in vitro of [1-¹⁴C]leucine into spinal cord proteins. The incorporation of [1-¹⁴C]leucine into slices of the inguinal and popliteal lymph nodes of the EAE and Freund's adjuvant control rats were measured and compared with the incorporation into the spinal cord non-myelin fractions. The specific activity of lymph node proteins was of the order of 10 × that of the non-myelin protein of the control spinal cord. Invasion of a moderate number of cells of the order of activity of these lymph nodes could account for the large increase in rate of protein synthesis in the EAE nervous tissue. It is concluded that much of the increased protein synthesis could be due to the inflammatory cells, although a small amount of the total increase appears to be associated with myelin protein. Other changes in metabolism of the CNS tissue of the EAE rat include a lower rate of lipid synthesis and a decreased activity of the tricarboxylic acid cycle.     

Biochemical Analysis of Myelin Proteins in a Novel Neurological Mutant: The Taiep Rat

Abstract: Hemispheres, spinal cords, and sciatic nerves were taken from taiep, carrier, and control rats at ages ranging from 1 day to 16 months. Absolute myelin yields from CNS taiep tissues peaked at ～2 months and then decreased until they reached a low but stable level. Myelin yield from the affected hemispheres expressed as a percentage of age-matched controls decreased continuously from 2 weeks until it reached a stable level of ～10–15%. The same was true for the spinal cords, but here the myelin yield reached a plateau at a slightly higher percentage of 20–25%. In comparison with control rats, isolated CNS myelin fractions from the affected rats had a greater content of high molecular weight proteins. Western blot analyses of CNS homogenates revealed that myelin basic protein (MBP), proteolipid protein, and 2′,3′-cyclic nucleotide 3′-phosphodiesterase were all present but decreased to levels generally consistent with the deficiencies of myelin. However myelin-associated glycoprotein (MAG) levels always were reduced much more than those of the other three myelin proteins, and at younger ages the apparent molecular weight for MAG was increased in the mutants. Western blot analyses of sciatic nerve homogenates showed that the levels of MBP, MAG, and P₀ were not significantly different in control and mutant animals. These results suggested an early hypomyelination of the CNS, with peak levels of myelin at 2 months, followed by a prolonged period of myelin loss, until a very low but stable myelin level was reached. The consistently greater loss of MAG, in comparison with other CNS myelin proteins, is different from most other hypomyelinating mutants in which MAG is relatively preserved in comparison with the proteins of compact myelin. This might be due to microtubular abnormalities in the taiep mutant interfering with transport of myelin proteins and having the greatest effect on MAG because of its most distal location in the periaxonal oligodendroglial membranes.     

STUDIES ON THE MECHANISM OF DEMYELINATION: TRIETHYL TIN-INDUCED DEMYELINATION

The metabolism of myelin undergoing breakdown as a result of edema induced by chronic administration of triethyl tin (TET) dissolved in the drinking water (10 mg/l.) was examined. The spinal cord showed more edema and loss of myelin than the brain. Uptake in vitro of [1-¹⁴C]acetate into myelin lipids of slices of brain or spinal cord from TET-treated rats was depressed until 4–5 weeks after the beginning of the regime, then rose to above normal levels. The uptake of [l-¹⁴C]leucine into myelin protein rose within several weeks of TET treatment to levels averaging over 300 per cent of normal and remained high even after the TET was removed. The high levels of [l-¹⁴C]leucine incorporation were inhibited by cycloheximide and were not explained by an increase in the size of the free amino acid pool. The three classes of myelin proteins, basic, proteolipid protein, and Wolfgram protein shared in the increased incorporation. Spinal cord myelin showed the greatest metabolic response, brain stem myelin less, and myelin from the forebrain was minimally affected by the TET treatment. Myelin prelabelled by intracisternal injection of [l-¹⁴C]acetate and [l-¹⁴C]leucine before the onset of TET administration showed faster turnover in myelin proteins in relation to the myelin lipids than the control in the most severely affected animals, but not in others less affected. A ‘floating fraction’ was observed floating on 10.5% (w/v) sucrose during the myelin purification. This fraction showed metabolic characteristics typical of myelin, and myelin-labelling studies at various stages of the animal's development showed it to be derived from recently synthesized myelin. The floating fraction from the brain contained less cerebroside and more lecithin than myelin, while the spinal cord floating fraction composition was much like that of myelin. The floating fractions contained less protein typical of myelin (basic and proteolipid protein) and more highmolecular-weight protein which may have been derived from contaminating microsomes. The floating fraction was presumed to be partially deproteinated myelin. The use of TET-treatment as model for demyelination as a result of edema and proceeding in the absence of macrophages is discussed.     

EVIDENCE FOR THE CLOSE ASSOCIATION OF A GLYCOPROTEIN WITH MYELIN IN RAT BRAIN

Abstract— Myelin was purified from rats which had been injected intracerebrally with radioactive fucose in order to label specifically the glycoproteins. Myelin contained a small amount of fucose-labelled glycoproteins in comparison to that in other subcellular fractions, but polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulphate revealed a unique pattern of radioactive glycoproteins dominated by a major peak. The same glycoprotein was not prominent in the other subcellular fractions which were examined. This major glycoprotein in the myelin fraction was also labelled after injection with [³H]glucosamine or N -[³H]acetylmannosamine. It was the most intensely staining myelin protein when gels were treated with periodic acid-Schiff reagents, an indication that, in terms of protein-bound carbohydrate, it is the major glycoprotein in the myelin fraction. The glycoprotein was present in myelin purified from rats ranging in age from 14 days to 14 months. Extensive recycling of the myelin through the purification procedures did not significantly reduce the amount of glycoprotein in the myelin. Double label experiments with [³H]fucose and [¹⁴C]fucose were used to compare glycoproteins in myelin purified from white and grey matter, respectively, and from mixed homogenates of myelinated and unmyelinated brain. The results obtained from these experiments suggested that the glycoprotein is closely associated with myelin and that it is not in an unrelated contaminating structure. Possible locations of the glycoprotein are discussed. They include the myelin membrane itself, the oligodendroglial plasma membrane, and the axolemma of myelinated axons.     

Myelin metabolism in vitro in experimental allergic encephalomyelitis

Abstract— Spinal cord slices from rats in different stages of allergic encephalomyelitis (EAE) were incubated with [U-¹⁴C]glucose. Normal rats and rats injected with Freund's adjuvant served as controls. The slices were fractionated by a discontinuous sucrose gradient into purified myelin and a heavy membrane residue, the lipids and proteins were extracted, and their specific activities were determined. Uptake of ¹⁴C into myelin lipids was depressed in the rats with acute EAE, while an increase was shown in myelin protein and heavy membrane lipids and proteins. The increased synthesis in non-myelin fractions was ascribed to invasion of metabolically active cells. The depression in myelin lipid synthesis occurred early in the disease before lesions appeared or the inflammatory reaction became widespread. Myelin from guinea pigs with acute EAE resulting from injection of a purified basic protein also showed a depression of uptake in both lipids and proteins. It is suggested that a metabolic insult as a result of the immunological process is dealt the oligodendroglial cells early in the course of the disease which leads to a weakening of the myelin sheath and subsequent phagocytosis of myelin.     

Characterization of the lipid and protein contents of myelin bodies isolated from the renal cortex of gentamicin-treated rats.

Myelin bodies were isolated from the renal cortex of gentamicin-treated rats (100 mg/kg body weight, twice daily for 3 days, i.p.) employing an initial pelleting by differential centrifugation and subsequent flotation on a discontinuous sucrose gradient. These structures were found to contain almost twice as much protein as phospholipid and SDS-polyacrylamide gel electrophoresis revealed the presence of many different polypeptides. All the major phospholipids are present, although myelin bodies contain a considerably higher proportion of phosphatidylinositol, somewhat more phosphatidylcholine and considerably lower percentages of phosphatidylserine and sphingomyelin than do normal renal phospholipids. The fatty acids of myelin body phospholipids are highly saturated (67.3-87.9%) and a striking feature is the occurrence of relatively large amounts of 22:1, presumably erucic acid, especially in sphingomyelin. Myelin bodies contain small amounts of unesterified cholesterol, unesterified dolichol and coenzymes Q9 and Q10.     

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.     

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.     

A regional survey of myelin development: some compositional and metabolic aspects

A survey of differences in composition and metabolism of myelin from five areas of the central nervous system was made in brain and spinal cord slices of the rat from 20 days to 20 months postnatal age. Purified myelin from the forebrain areas showed a composition characteristic of immaturity longer than did myelin from the hindbrain and spinal cord. The trend of chemical maturity is in agreement with the anatomical observations that myelination begins in the hindbrain and proceeds rostrally. Myelin recovery per 100-mg slice increased continually from 20 days to 20 months of age, while the uptake of [1-(14)C]acetate into myelin lipid and of [1-(14)C]leucine into myelin protein decreased precipitously with age. Taking into account the continuous increase in myelin during maturation, a calculation was made of the total amount of incorporation of labeled material into lipids or proteins per 100-mg slice for each region at each age. The metabolic characteristics of myelin from the cerebral cortex (including the corpus callosum), the thalamic area, and the cerebellum were very similar, while myelin from brainstem and spinal cord was metabolically more active, especially at the early ages. Synthesis of lipid in the myelin sheath represents about 50% of the lipid synthesis of the whole brain and about 75% of that of the spinal cord. The proportion of myelin-related protein synthesis is much less, probably less than 10% of the protein synthesis occurring in whole brain and about 15% of that in the spinal cord except at early ages.     

Myelin Deficits Produced by Early Postnatal Exposure to Inorganic Lead or Triethyltin Are Persistent

Abstract: Long-Evans rat pups were exposed to either inorganic lead (400 mg Pb as lead acetate/kg body weight/day) or triethyltin sulfate (1.0 mg/kg body weight/day), by gastric intubation, from 2 days through 29 days of age. The rats were then weaned and placed on standard lab chow ad libitum. At 30 days of age, leadtreated rats exhibited statistically significant decreases in body and brain weights (22% and 17%, respectively), and the concentration of forebrain myelin was significantly reduced, by 21% relative to the 4.9 mg myelin protein/g brain in control rats. Although these animals recovered from the body weight deficits after several months, the deficits in brain weight and myelin concentration were still present at 120 days of age. This suggests that the lead-induced myelin deficits were permanent. Lead levels in brain, which were maximal at 30 days of age when the treatment was terminated, decreased more slowly than in other organs and were still 30% of maximal levels at 120 days of age. Triethyltin-treated animals also had significantly decreased body and brain weights (20% and 11%, respectively) at 30 days of age, and an even more severe reduction in forebrain myelin concentration (33%). These animals also regained a normal body weight by 120 days of age, but again the deficits in brain weight and myelin concentration persisted. Tin levels in brain and other organs had decreased to control levels by 60 days of age. Animals malnourished by maternal deprivation to match the body weights of the treated animals had myelin deficits that were less severe than those in the treated animals at 30 days of age (approximately 11% less than controls); however, these myelin deficits also persisted throughout the subsequent 90-day recovery period examined. The apparent lack of recovery from CNS myelin deficits produced by neonatal exposure to different heavy metals or to malnutrition reemphasizes the vulnerability of the developing nervous system to a wide range of metabolic insults.     

Light aerobic physical exercise in combination with leucine and/or glutamine-rich diet can improve the body composition and muscle protein metabolism in young tumor-bearing rats

Nutritional supplementation with some amino acids may influence host??s responses and also certain mechanism involved in tumor progression. It is known that exercise influences body weight and muscle composition. Previous findings from our group have shown that leucine has beneficial effects on protein composition in cachectic rat model as the Walker 256 tumor. The main purpose of this study was to analyze the effects of light exercise and leucine and/or glutamine-rich diet in body composition and skeletal muscle protein synthesis and degradation in young tumor-bearing rats. Walker tumor-bearing rats were subjected to light aerobic exercise (swimming 30?min/day) and fed a leucine-rich (3%) and/or glutamine-rich (4%) diet for 10?days and compared to healthy young rats. The carcasses were analyzed as total water and fat body content and lean body mass. The gastrocnemious muscles were isolated and used for determination of total protein synthesis and degradation. The chemical body composition changed with tumor growth, increasing body water and reducing body fat content and total body nitrogen. After tumor growth, the muscle protein metabolism was impaired, showing that the muscle protein synthesis was also reduced and the protein degradation process was increased in the gastrocnemius muscle of exercised rats. Although short-term exercise (10?days) alone did not produce beneficial effects that would reduce tumor damage, host protein metabolism was improved when exercise was combined with a leucine-rich diet. Only total carcass nitrogen and protein were recovered by a glutamine-rich diet. Exercise, in combination with an amino acid-rich diet, in particular, leucine, had effects beyond reducing tumoral weight such as improving protein turnover and carcass nitrogen content in the tumor-bearing host.     

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.     

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.     

Chronic early leucine administration induces behavioral deficits in rats.

Sustained levels of leucine comparable to those of human Maple Syrup Urine Disease (MSUD) were achieved in blood and brain of rats by subcutaneous leucine administration twice a day from the 6th to the 28th day of life. Control rats were treated with saline in the same volumes. Behavioral studies using aversive and nonaversive tasks were performed during adult age. Chronic early leucine treatment impaired acquisition of a two-way shuttle avoidance task and altered habituation to an open field. Our results suggest that early postnatal leucine administration induces long-lasting behavioral deficits.