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.     

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.     

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.     

Lipid composition of rat brain myelin in triethyl tin-induced edema

Chronic triethyl tin intoxication was induced in young adult rats by oral feeding of triethyl tin sulfate. Progressively severe brain edema developed during the 3-month experimental period. The yield of myelin from the brains of the experimental animals decreased to almost half normal per brain, but the isolated myelin appeared morphologically normal. The analysis of whole brain showed corresponding decreases in proteolipid protein and total lipid, particularly galactolipids. The proportions of the major constituents of isolated myelin (chloroform-methanol-insoluble residue, proteolipid protein, and total lipid) were unchanged despite the low yield. However, the proportion of cholesterol increased from 16 to 21% dry weight, and that of total galactolipid decreased from 21 to 15%, as the yield of myelin decreased. This decrease of total galactolipid was mainly due to the decrease in cerebroside. Total phospholipid remained constant initially but showed a slight decrease toward the end of the experiment, due mostly to decreased ethanolamine phospholipid. There was no preferential loss or preservation of phosphatidalethanolamine. The fatty acid composition of sulfatide showed statistically significant shifts to less long-chain fatty acids and less monoenoic acids, but cerebroside and sphingomyelin did not show significant changes in the fatty acid composition. There was no increase in esterified cholesterol. These findings generally support our hypothesis of nonspecific chemical abnormalities of the myelin sheath undergoing secondary degeneration. In an acute experiment, a single intraperitoneal injection of triethyl tin sulfate produced acute and transient brain edema. There were slight decreases in the yield of myelin, but no detectable changes in the chemical composition.     

Poster Sessions BP03: Myelin,Demyelination and Diseases of Myelin. Myelin and myelination in PLP‐null mice

The myelin proteolipid protein (PLP) is the major structural protein of CNS myelin, accounting for approximately half of total myelin protein. We studied synthesis and accumulation of myelin components for two months postnatally in PLP‐null mice and age‐matched controls. Accumulation of myelin, as assayed by levels of whole brain cerebroside and myelin basic protein, was normal in the knockout mice. The rate of cerebroside synthesis in the knockout mice was also normal. Myelin was isolated at several ages during development, using a standard subcellular fractionation protocol. The yield of ‘purified myelin’ isolated from a large particle (crude mitochondrial) fraction was reduced in PLP‐null mice, but increased amounts of ‘myelin’ were obtained in the small particle (crude microsomal) fraction. This ‘myelin’ in the crude microsomal fraction was identified as such by flotation on 0.85 m sucrose and the myelin‐characteristic 2 : 1 molar ratio of cholesterol to cerebroside. This suggests myelin from PLP‐null mice is physically more fragile than normal myelin, and that during tissue dispersion, much more PLP‐null myelin is fragmented into small vesicles than is the case for normal myelin. Three hours after intracranial injection of tritiated acetate into PLP‐null mice, cerebroside in myelin isolated from the large particle fraction was at a similar specific radioactivity to that isolated from the small particle (crude microsomal) fraction, suggesting that the most recently deposited PLP‐null myelin is not preferentially unstable. The increased fragility evident during tissue dispersion is indicative of an underlying structural abnormality in PLP‐null myelin. Whether this inherent structural instability affects myelin metabolism is under investigation. Acknowledgements: Supported by USPHS & NMSS grants.     

Effect of inorganic lead exposure on myelination in the rat

The effect of defined lead burdens on myelination of the central and peripheral nervous systems was studied in neonatal Long-Evans rats. Pups were exposed to inorganic lead (100 or 400 mg Pb as lead acetate/kg body wt/day by gastric intubation) from day 2 following birth to 30 days of age. Accumulation of myelin in forebrain was not affected by the 100-mg dosage, but at the 400 mg/kg dosage level, myelin accumulation was reduced by approximately 42% on a per gram forebrain basis relative to vehicle-intubated animals. The deficit was over 50% on a per forebrain basis, since there was also a slight reduction in brain weight. This lead effect was observed at both 15 and 30 days of age. Accumulation of myelin in optic nerve (determined on the basis of proteolipid protein concentration) was also reduced by 30% relative to controls by this dosage level. However, myelination in sciatic nerve (determined on the basis of P₀ protein concentration) was not affected by this exposure regimen. Myelin deficits were greater than could be accounted for by undernutrition arising secondary to lead exposure and were not due to a developmental delay in the onset of 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.     

Adrenalectomy of Rats Results in Hypomyelination of the Central Nervous System

The effect of adrenalectomy on CNS myelin accumulation was investigated to determine whether glucocorticoids play a role in regulating myelination. When 14-day-old rats were adrenalectomized and sacrificed 7-8 days later, the amount of bulk-isolated myelin in whole brain, as expressed per gram wet weight of brain or per milligram DNA-phosphate, was reduced to about 75% that of sham-operated controls. Both brain weight and DNA content were unchanged by adrenalectomy. Examination of individual brain regions also revealed decreased amounts of myelin in adrenalectomized animals. Brain glycerol 3-phosphate dehydrogenase specific activity was reduced in adrenalectomized animals to 40-60% that of controls, and serum corticosterone levels were less than 0.6% of control levels. The amount of cerebral myelin in animals adrenalectomized on day 21 and sacrificed 9 days later was not significantly reduced. This suggests a possible role of glucocorticoids during the early period of rapid myelination.     

Cerebroside synthesis as a measure of the rate of remyelination following cuprizone-induced demyelination in brain

We studied markers of myelin content and of the rate of myelination in brains of mice between 8 and 20 weeks of age. During the 12-week time-course, control animals showed slight increases in the content of oligodendroglial-specific cerebroside, as well as cholesterol (enriched in, but not specific to, myelin). In contrast, synthesis of these lipids, as assayed by in vivo incorporation of (3)H(2)O, was substantial, indicating turnover of 0.4% and 0.7% of total brain cerebroside and cholesterol, respectively, each day. We also studied mice exposed to a diet containing 0.2% of the copper chelator, cuprizone. After 6 weeks 20%, and by 12 weeks, over 30% of brain cerebroside was gone. Demyelination was accompanied by down-regulation of mRNA expression for enzymes controlling myelin lipid synthesis (ceramide galactosyl transferase for cerebroside; hydroxymethylglutaryl-CoA reductase for cholesterol), and for myelin basic protein. Synthesis of myelin lipids was also greatly depressed. The 20% cerebroside deficit consequent to 6 weeks of cuprizone exposure was restored 6 weeks after return to a control diet. During remyelination, expression of myelin-related mRNA species, as well as cerebroside and cholesterol synthesis were restored to normal. However, in contrast to the steady state metabolic turnover in the control situation, all the cerebroside and cholesterol made were accumulated. To the extent that accumulating cerebroside is targeted for eventual inclusion in myelin (discussed) the rate of its synthesis is proportional to remyelination. With our assay, in vivo rates of cerebroside synthesis can be determined for a time window of the order of hours. This offers greater temporal resolution and accuracy relative to classical methods assaying accumulation of myelin components at time intervals of several days. We propose this experimental design, and the reproducible cuprizone model, as appropriate for studies of how to promote remyelination.     

EARLY POSTNATAL STARVATION CAUSES LASTING BRAIN HYPOMYELINATION

Abstract— Rats were starved during various intervals of postnatal development, and subsequently, they were rehabilitated by feeding ad lib. through 60 days of age. Starvation was induced by an increasingly severe regime of maternal deprivation that results in a 50% deficit in body weight at 20 days. Relatively mild and brief starvation, from birth through 8 days, as well as more severe starvation occurring late, from 14 to 30 days, produced no lasting deficit in myelin accumulation. Starvation from birth through 14 days or from birth through 20 days produced lasting, significant myelin deficits in all regions (cerebrum, cerebellum, medulla, midbrain, hippocampus, hypothalamus, and striatum) of the brain. These data, in combination with our previous metabolic studies of myelin synthesis of starved and control rats, show that starvation early in development, during the period of oligodendroglial cell multiplication, accounts for an immediate reduction in myelin synthesis, and that the consequent myelin deficit proves irreversible in subsequent nutritional rehabilitation. In contrast, brain weight is subject to substantial growth catch-up upon rehabilitation. Where the onset of starvation was late, during the period of rapid myelin synthesis, but after completion of the major period of oligodendroglial cell proliferation, no lasting myelin deficit was observed upon rehabilitation.     

Protein Synthesis Rates in Rats with Portacaval Shunts

Abstract: Protein synthesis rates were measured (33 days postoperatively) in rats with portacaval shunts and in unoperated controls. In brain, no change in the rate of protein synthesis was evident in shunted rats. These data thus do not support the hypothesis that an inhibition of brain protein synthesis is a factor in the etiology of hepatic encephalopathy. The synthesis rate in forebrain at 82 days of age was 0.52%/h. Though brain wet weight was the same in both groups, rats with shunts grew relatively slowly, and their testicles probably decreased in weight. However, no inhibition of muscle, liver, or testicular protein synthesis could be detected. The mechanism of slower or negative growth in these tissues might thus involve an increase in the degradation rate, although a transient inhibition of synthesis at an earlier period is also possible.     

BIOCHEMICAL CHARACTERIZATION OF A MYELIN FRACTION ISOLATED FROM RAT BRAIN AGGREGATING CELL CULTURES

Abstract— Subcellular fractions isolated from rat brain aggregating cell cultures were studied by electron microscopy and showed the presence of typical myelin membranes. The chemical composition of purified culture myelin was similar to the fraction isolated from rat brain in terms of CNP specific activity, protein and lipid composition. The ratio of small to large components of myelin basic protein was comparable in culture and in vivo. These two proteins incorporated radioactive phosphorus. The major myelin glycoprotein was present and during development in culture its apparent molecular weight decreased although it never reached the position observed in myelin isolated from adult rats. In culture, the yield of myelin did not increase substantially between 33 and 50 days and was comparable to that of 15-day-old rat brain. The ratio basic protein to proteolipid protein resembled immature myelin and the cerebroside content was very low. A 'floating fraction' was isolated from the cultures and contained some myelin but mostly single membranes. Although these results indicate that myelin maturation is delayed in vitro this culture system provides substantial amounts of purified myelin to allow a complete biochemical analysis and metabolic studies during development.     

INCORPORATION OF LIPIDS INTO SUBCELLULAR FRACTIONS OF BRAIN OF QUAKING MUTANT

The synthesis of lipids and their assembly into subcellular membrane fractions of the myelin deficient Quaking mutant and control brains was studied in 18-, 24- and 41-day-old animals using a double label methodology with¹⁴C and ³H acetate as precursors. As a general procedure, Quaking mutants were injected intracranially with 50 μCi [¹⁴C]acetate and their littermate controls with 300 μCi [³H]acetate. The animals were killed 3 h post-injection, their brains were pooled and subcellular fractions prepared from the common homogenate. An 80-90% decrease in the incorporation of acetate into eleven lipids of myelin in the Quaking mutant was found. This occurred in the face of apparent normal incorporation (relative to microsomes) into lipids of the other main subcellular fractions (nuclear. mitochondrial and synaptosomal) with the exception of decreased incorporation into the myelin-like fraction at 18 and 24 days. Cholesterol and cerebroside were less readily incorporated into Quaking myelin than the other lipids. Although the microsomal synthesis of cholesterol and cerebroside was depressed by about 30% in the Quaking mutant, the incorporation of cholesterol into nuclear, synaptosomal and mitochondrial fractions was unaffected in the mutant. This indicates that sufficient cholesterol is synthesized for the normal assembly of these organelles. In contrast the incorporation of acetate into cholesterol and cerebroside of Quaking myelin was decreased much more than microsomal synthesis. This latter result is consistent with a defect in the process of myclin membrane assembly     

Parameters related to lipid metabolism as markers of myelination in mouse brain

Myelination, during both normal development and with respect to disorders of myelination, is commonly studied by morphological and/or biochemical techniques that assay as their end-points the extent of myelination. The rate of myelination is potentially a more useful parameter, but it is difficult and time-consuming to establish, requiring a complete developmental study with labor-intensive methodology. We report herein development of methodology to assay the absolute rate of myelination at any desired time during development. This involves intraperitoneal injection of (3)H(2)O to label body water pools, followed by determination of label in the myelin-specific lipid, cerebroside. The absolute amount of cerebroside synthesized can then be calculated from the specific radioactivity of body water and knowledge of the number of hydrogens from water incorporated into cerebroside. During development, the rate of cerebroside synthesis correlated well with the rate of accumulation of the myelin-specific components, myelin basic protein and cerebroside. For purposes of control, we also tested other putative, albeit less quantitative, indices of the rate of myelination. Levels of mRNA for ceramide galactosyltransferase (rate-limiting enzyme in cerebroside synthesis) and for myelin basic protein did not closely correlate with myelination at all times. Cholesterol synthesis closely matched the rate of cholesterol accumulation but did not track well with myelination. Synthesis of fatty acids did not correlate well with accumulation of either fatty acids (phospholipids) or myelin markers. We conclude that measurement of cerebroside synthesis rates provides a good measure of the rate of myelination. This approach may be useful as an additional parameter for examining the effects of environmental or genetic alterations on the rate of myelination.     

How much undernourishment is required to retard brain myelin development.

This study employs a large population of developing rats designed to range continuously from above a normal, average weight to severely undernourished. The purpose of the study is to determine if brain myelin development is vulnerable to mild growth retardation from chronic hunger, or if brain myelin development is altered only after a certain tolerable amount of growth retardation is exceeded. The brains were examined at a landmark age, weaning, since myelination is one of the most vulnerable features of brain development and its rate of synthesis is highest at this age. Brain size was logarithmically related to body weight, and brain growth retardation increased as the severity of food deprivation increased. There was an additional reduction in the concentration of brain myelin. In contrast to brain weight, the reduction in myelin concentration was linearly related to body size over the full range from well nourished to undernourished. From a population perspective, these data indicate growth retardation from undernourishment in any amount slows brain growth and additionally lowers the concentration of brain myelin; however, individuals, in both well nourished and undernourished groups, vary widely. Implications and cautions of extrapolation to human populations are discussed.     

Beta-adrenergic receptor in heart of starved rats

Female Wistar-strain rats were starved for 14-19 days by feeding approximately 1/4 of the amount consumed by ad libitum fed controls. The body weight was reduced by 41% and the heart weight by 38% in these starving periods. The 125I-iodocyanopindrol (ICYP) binding capacity of heart preparations from the starved rats was 35.3 +/- 11.1 (mean +/- SD) fmol/mg protein in comparison with 69.3 +/- 14.9 for the controls. Serum 3,5,3'-triiodothyronine (T3), thyroxine and TSH levels as well as pituitary TSH contents were markedly lower in the starved rats. One group of them further received 20 ng of T3 daily after the 8th day of the experiment. The body weight decreased by 47% of the controls but the ICYP binding capacity recovered to 56.3 +/- 10.9 fmol/mg protein. There was no difference in association constants of the receptors in these three groups. It was concluded that quasi-chronic starvation in rats caused a remarkable decrease in the number of beta-adrenergic receptors in heart and this was partly offset by the substitution of T3.     

Biochemical Expression of Mosaicism in Female Mice Heterozygous for the Jimpy Gene

Abstract: Expression of the jimpy gene in heterozygous females was analyzed by measuring galactolipid synthesis in brain during early myelination. Sulfatide labeling in brains of heterozygous females at 13–14 days is decreased to 40–80% that of female littermates who do not carry the jimpy gene. The activities of ceramide galactosyl transferase and cerebroside sulfotransferase and levels of myelin basic protein were similarly depressed. Since the jimpy gene was maintained with the Tabby gene in these studies, the effect of the Tabby gene on these parameters was examined and found to have no effect. These biochemical findings indicate that myelination is retarded in the brains of heterozygous jimpy females during the second week of development. However, at 18 days and thereafter, sulfatide labeling is less reduced, suggesting that the oligodendrocytes in brain attempt to compensate, in agreement with morphologic studies which show that myelin is decreased in brain during early development, but appears normal in adult animals.     

The effects of 6 hours of hypoxia on protein synthesis in rat tissues in vivo and in vitro.

Rates of protein synthesis were measured in vivo in several tissues (heart, skeletal muscles, liver, tibia, skin, brain, kidney, lung) of fed rats exposed to O2/N2 (1:9) for 6 h starting at 08:00-11:00 h. Protein synthesis rates were depressed by 15-35% compared with normoxic controls in all of the tissues studied. The decreases were greatest in the brain and the skin. Although hypoxia inhibited gastric emptying, its effects on protein synthesis could probably not be attributed to its induction of a starved state, because protein-synthesis rates in brain and skin were not decreased by a 15-18 h period of starvation initiated at 23:00 h. Furthermore, we showed that protein synthesis was inhibited by hypoxia in the rat heart perfused in vitro, suggesting a direct effect. The role of hypoxia in perturbing tissue nitrogen balance in various physiological and pathological states is discussed.     

BIOCHEMICAL DEVELOPMENT OF RAT FOREBRAINS IN SEVERE PROTEIN AND ESSENTIAL FATTY ACID DEFICIENCIES

The effect of a low-protein diet (6 calorie-% protein) and a low essential fatty acid diet EFA (0.1 calorie-% EFA) on the biochemical composition of the forebrain was compared with that of a control diet (16 calorie-% protein and 3.0 calorie-%: EFA). The low-protein diet was fed from 1 week before mating, while the other two diets were fed for more than two generations before mating. Four litters of each dietary group were assayed at 10, 15, 21, 30 and 120 days of age but only one sample from several litters of newborns. The forebrain growth was retarded between 10 and 15 days of age in the low-protein group, but afterwards the growth was faster than in the control group. Also the low-EFA group showed similar changes though less pronounced with retarded growth between 10 and 15 days of age. In the two deficiency groups the DNA content in the forebrain was reduced, but less than the weight. The gangliosides were used as a marker substance for neuronal membranes. In the low-protein group the normally rapid accretion of gangliosides between 10 and 15 days of age was significantly retarded, but afterwards faster than in the control group. From 30 days of age the ganglioside concentration was significantly higher in the low-protein group than in the control group. The low EFA diet resulted in similar but less pronounced changes than the low protein diet. The cerebroside content was lower in both the low-protein and low EFA groups at all ages than in the control group indicating a lower myelin content. The cerebroside content differed more than any other parameter studied. The findings suggest that severe nutritional deficiencies only delay the development of the neuronal membranes but irreversibly reduce the formation of myelin.     

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.