Effects of maternal thiamine deficiency on the lipid composition of rat whole brain, gray matter and white matter

Studies were made of the effects of maternal thiamine deficiency on rat whole brain, gray matter and white matter lipids. Mothers were fed a high protein diet (controls) or thiamine deficient high protein diet (thiamine deficient, TD) from 14th day of gestation through lactation. An additional group (pair fed control, PFC) was pair fed with the thiamine deficient group. The TD pups started showing symptoms of abnormalities in posture, arched back and hind limb paralysis from 16th day of lactation. Significant deficits were found in body weight and brain weight of TD and PFC pups. But the deficits seem to be more in the former group. Significant deficits were observed with regard to the concentration of lipids such as galactolipids, phospholipids and plasmalogens in the whole brain of TD and PFC pups at 21 days of age. Additional deficits were also found in the concentration of cholesterol in PFC pups. Gray matter lipids from TD pups seem to be completely spared. However, deficits were found in galactolipid and ganglioside concentrations in PFC pups. The deficits found in the concentration of different lipids in white matter are similar to those observed in whole brain. These results suggest that the effects of thiamine deficiency may be partly due to resultant growth retardation and partly due to the deficiency of thiamine per se.     

Effects of neonatal pantothenic acid deficiency on brain lipid composition in rats.

—Studies were made of the effects of pantothenic acid deficiency during the neonatal period on brain lipids in rats. Mothers with 6–8 pups to a litter were fed from soon after birth a diet either normal or deficient in pantothenate. An additional control group (restricted controls) was pair-fed with the deficient group. Significant deficits were found in the pups of the pantothenate-deficient group and in those of the restricted controls with regard to body weight, brain weight and brain concentration of lipids (total lipid, cholesterol, phospholipid, galactolipid and gangliosides) at 21 days of age. The deficits in both these groups were comparable. The results suggest that the effects of pantothenate deficiency may be due to the resulting growth deficit rather than to the deficiency of pantothenate per se.     

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.     

The effect on growth of feeding supplemental milk or baby food to the suckling rat

Suckling rats were fed synthetic rat milk or baby food as dietary supplements amounting to 10% of their total expected daily caloric intake from day 10 to day 16 of life. On day 17, their body lipid levels were significantly higher than those of control pups, and they remained high throughout a 6-week postweaning period of ad libitum food intake. Protein content (at 17 and 60 days of age) was similar in experimental and control groups. Seventeen-day-old pups that had been fed supplemental baby food showed a small but significant increase in DNA levels but no accompanying increase in lean body mass. Rats that received supplemental milk weighed more than either those that received baby food or controls at 17 days of age; however, both experimental groups weighed considerably more at weaning (21 days) than controls. At 60 days of age, their weights were again similar to those of control rats.     

Effect of postweaning protein deficiency on the content and lipid composition of gray and white matter in neonatally undernourished rat brain

The effects of neonatal undernutrition and postweaning protein deficiency on the content and lipid composition of gray and white matter of 63 days old rat brain have been studied. The concentrations of different lipids remain the same, but the relative proportion of gray and white matter changes thus reflecting the differences in the concentration of whole brain lipids.     

Multiple mechanisms account for lower plasma iron in young copper deficient rats

Copper deficiency lowers brain copper and iron during development. The reduced iron content could be due to hypoferremia. Experiments were conducted to evaluate plasma iron and “ferroxidase” hypotheses by determining copper and iron status of Holtzman albino rats following gestational/lactational copper deficiency. Copper deficient (Cu−) dams on treatment for 5 weeks, two of gestation and three of lactation, had markedly lower copper content of milk and mammary tissue, and lower milk iron. Newborn pups from Cu− dams had lower copper and iron concentrations. Compared to Cu+ pups, Cu− pups, analyzed between postnatal age (P) 0 and P26, were smaller, anemic, had lower plasma iron, cardiac hypertrophy, and near zero ceruloplasmin activity. Liver copper in Cu+ pups increased then decreased during development and major reductions were evident in Cu− pups. Liver iron in Cu+ pups decreased with age while nursing but increased after eating solid food. Liver iron was lower in Cu− pups at P0 and P13 and normal at P20 and P26. Small intestinal copper decreased with age in Cu+ pups and was lower in Cu− pups. Intestinal iron levels in Cu− pups were higher than Cu+ pups postweaning in some experiments. Reduction in plasma iron in Cu− pups is likely due to a decreased “ferroxidase” function leading to lower placental iron transport, a lower milk iron diet, and partial block in iron uptake from intestine but is not due to failure to mobilize hepatic iron, in contrast to older rats eating diet with adequate iron.     

Prenatal and postnatal protein restriction in the rat: effect on some parameters related to brain development, and prospects for rehabilitation.

Abstract— From the third day of pregnancy rats were fed a diet containing either 7% casein (experimental) or 24% casein (control). During lactation the control dams were fed the 24% casein diet and the experimental dams a 12% casein diet. From 25 to 50 days of age the experimental and control progeny were fed diets containing 7 and 24% casein, respectively. Between 50 and 120 days both groups were fed a diet containing 24% crude protein. Several indications of brain maturation in two brain areas were examined at various stages of development. In addition to retardation of brain growth, protein restriction led to myelin of an immature composition at 25 and 50 days of age. The immature composition was indicated by a low plasmalogen content at 25 days and by a high phospholipid and low galactolipid and plasmalogen contents at 50 days of age. The activity of the myelin marker enzyme, 2′3′-cyclic nucleotide 3′-phosphohydrolase (CNP), was significantly lower in the brains (excluding the cerebella) of malnourished rats at 21, 30 and 50 days. At all ages except at 50 days the activity of CNP in the cerebellum was higher in protein-deprived animals than in controls. The activity of glutamic acid decarboxylase (GAD) in the brains (excluding the cerebella) of protein-deprived rats was significantly lower at 21, 25 and 30 days but not at 50 and 65 days of age. As indicated by brain/body ratios, myelin composition and GAD activity, nutritional rehabilitation led to almost complete recovery of brain maturity, but the activity of CNP remained lower in the experimental group after rehabilitation.     

Effect of maternal iron deficiency on GABA shunt pathway of developing rat brain

Iron deficiency during pregnancy and lactation (35 mg iron/kg diet) produced a significant reduction in liver nonheme iron in dams as well as in fetus and young ones. The body, liver and brain weights of fetus, new-born, and developing pups remained unaffected. However, the body weight and PCV were reduced only in 21-day-old pups. The enzyme activities of GDH, GAD, GABA-transaminase, and NAD(+)-linked ICDH were reduced in 14 and 21-day-old pups. The enzyme activities of NADP(+)-linked ICDH activities remained unaffected in the fetus and developing pups brain. Maternal rehabilitation on iron sufficient diet for 1 week from day 14 to 21 of lactation period did not reverse these changes. The maternal iron deficiency during lactation period alone did not cause any alteration in all parameters assayed, however, there was a reduction in liver non-heme iron of pups on days 14 and 21.     

Effects of Neonatal Undernutrition on the Lipid Composition of Gray Matter and White Matter in Rat Brain

Abstract: Separate analyses were made of gray matter and white matter from rat brain after neonatal undernutrition. Newborn rats were redistributed into control, large-litter, and protein-deficient groups. Large litters had 16 rather than 8 pups with a dam. Protein-deficient dams were fed a 4%, instead of a 24%, casein diet. For controls at 21 days of age, the 2',3'-cyclic nucleotide-3'-phosphohydrolase activity was more than fivefold greater in white matter than in gray matter. Severe undernutrition (protein-deficient) gave 2',3'-cyclic nucleotide-3'-phosphohydrolase activities that were 36% lower in gray matter and 56% lower in white matter. Lipid galactose concentrations were 17% less than control in both gray matter and white matter. In protein-deficient white matter, phospholipid concentrations were 15% lower than control. Ethanolamine plasmalogens and phosphatidyl serine were affected most. Moderate undernutrition (large litter) had no effect on 2',3'-cyclic nucleotide-3'-phosphohydrolase activity. A 14% deficit of galactolipids was the only difference from controls in large-litter white matter. In large-litter gray matter, phospholipid concentrations were 16% higher than controls. Nearly all glycerophos-pholipids, including plasmalogens, were affected. With the exception of the myelination markers, 2',3'-cyclic nucleotide-3'-phosphohydrolase and lipid galactose, the development of lipids in gray matter is almost completely spared from the effects of undernutrition. The primary effect of undernutrition is on myelination, especially in white matter.     

The effects of pyridoxine deficiency and of caloric restriction on lipids in the developing rat brain

Abstract— The effects of dietary deficiency of pyridoxine upon the contents of lipids in the brain were determined at several times after birth for three groups of rats. The mothers of the nursing pups were fed one of the following dietary regimes: pyridoxine-deficient diet ad lib., pyridoxine-supplemented diet ad lib., or pyridoxine-supplemented diet in restricted amounts. At 7 and 14 days of postnatal age there were no significant differences between supplemented and deficient animals for any of the cerebral lipids studied. At 21 days the content of sphingomyelin in the brains of deficient animals was significantly lower than that in brains from the supplemented or calorically restricted animals in terms of percentage of total lipid and phospholipid phosphorus or tissue weight. On a per brain basis the content of sphingomyelin in the brains of calorically-restricted rats was significantly lower than in the brains of rats fed the supplemented diet ad lib. The contents of cerebrosides but not of sulphatides or ceramides were also significantly lower in brains of the deficient group than in brains from the other two groups. The contents of pyridoxine in brains and in livers of the deficient animals were considerably lower than the contents found in the same organs of the other dietary groups. The results suggest that one reason for the abnormal development of the brains of rats on a pyridoxine-deficient diet during the early postnatal period may be due to decreased quantities of sphingolipids.     

Developmental changes in rat blood choline concentration.

1. Serum choline concentration in the newborn rat is extremely high and declines as the rat matures until adult values are attained at 20 days of age. 2. Rat milk is a rich source of choline, and rat pups denied access to milk had significantly lower serum choline concentrations than did fed littermates. We conclude that dietary intake of choline contributes to the maintenance of high serum choline concentrations in the neonatal rat. 3. In vivo, choline disappears with a half-life of 70 min. It is converted into betaine, phosphocholine and phosphatidylcholine. The rate of phosphocholine formation is identical in 3- and 10-day-old rats (3.3 mumol/h), whereas the rate of betaine formation is slower in younger animals (0.15 mumol/h at 3 days versus 0.69 mumol/h at 10 days). In vitro, choline oxidase activity [choline dehydrogenase (EC 1.1.99.1) and betaine aldehyde dehydrogenase (EC 1.2.1.8)] increased between birth and 40 days of age. The age-related acceleration in choline's conversion into betaine probably tends to diminish unesterified choline concentration in the rat.     

Demonstration of a quiescent period for feeding controls in the developing rat

Feeding behaviour of rats during development was assessed by weighing pups before and after a 4 h feeding session. During the first postnatal week, fasted pups gained significantly more weight than fed pups. This difference disappeared during the second week, but reappeared during the third week and persisted through the fourth week. In another series, pups were weighed at 2 and 4 h after beginning feeding. This showed that fasted pups aged 6 days compensate by suckling longer than fed pups. At 10 and 14 days of age there were no differences between fed and fasted pups at either 2 or 4 h, but from 16 days onward, fasted pups had eaten significantly more than fed pups at both times. A control experiment showed that the lack of compensation by fasted pups aged 10-14 days did not reflect lack of availability of milk. Video-analysis of suckling behaviour at ages 6, 10 and 15 days provided further evidence for lack of feeding controls during the second postnatal week: at 6 and 15 days fasted pups spent more time actively sucking than did fed pups. Whereas at 10 days, there were no differences between fed and fasted pups. It is concluded that feeding controls are present during the first postnatal week, become quiescent during the second week and reappear during the third week.     

Effect of Maternal Alcohol Consumption on the Lipid Composition of CNS in the Offspring

Maternal alcohol consumption at a level that does not affect calorie intake increases cholesterol concentration and content as well as incorporation of labeled glucose into cholesterol in the brain and spinal cord of newborn rat pups. Continued consumption of alcohol during lactation also affects the galactolipid concentration in the brain and spinal cord of pups at 21 days of age, and this increase seems mainly to be due to an increase in content of myelin lipids. Analysis of myelin shows that the concentration of phospholipids also increases in this fraction. The increase in incorporation of labeled glucose into these membrane lipids suggests an increase in the synthesis of these lipids, which prevents fluidization of the membrane by alcohol. That in the brainstem the increase in levels of cholesterol and galactolipids is higher than in other regions and that there is also an increase in content of sphingomyelin, phosphatidylcholine, and phosphatidylethanolamine suggest that the brainstem needs better protection against fluidization.     

Leptin levels in rat offspring are modified by the ratio of linoleic to alpha-linolenic acid in the maternal diet

The supply of polyunsaturated fatty acids (PUFA) is important for optimal fetal and postnatal development. We have previously shown that leptin levels in suckling rats are reduced by maternal PUFA deficiency. In the present study, we evaluated the effect of maternal dietary intake of (n-3) and (n-6) PUFA on the leptin content in rat milk and serum leptin levels in suckling pups. For the last 10 days of gestation and throughout lactation, the rats were fed an isocaloric diet containing 7% linseed oil (n-3 diet), sunflower oil (n-6 diet), or soybean oil (n-6/n-3 diet). Body weight, body length, inguinal fat pad weight, and adipocyte size of the pups receiving the n-3 diet were significantly lower during the whole suckling period compared with n-6/n-3 fed pups. Body and fat pad weights of the n-6 fed pups were in between the other two groups at week one, but not different from the n-6/n-3 group at week 3. Feeding dams the n-3 diet resulted in decreased serum leptin levels in the suckling pups compared with pups in the n-6/n-3 group. The mean serum leptin levels of the n-6 pups were between the other two groups but not different from either group. There were no differences in the milk leptin content between the groups. These results show that the balance between the n-6 and n-3 PUFA in the maternal diet rather than amount of n-6 or n-3 PUFA per se could be important for adipose tissue growth and for maintaining adequate serum leptin levels in the offspring.     

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.     

Effects of maternal marginal zinc deficiency on myelin protein profiles in the suckling rat and infant rhesus monkey

In the current study, the effects of marginal Zn deficiency on myelin protein profiles in neonatal rats and rhesus monkeys were investigated. Following mating, rats were fed a Zn-adequate diet,ad libitum (50 μg Zn/g; 50 Zn AL), or a marginal Zn diet (10 μg Zn/g) from day 0 (10 Zn d0) or day 14 (10 Zn d14) of gestation to day 20 postnatal. An additional group of dams was restricted-fed the control diet to the food intake of the 10 Zn d0 group (50 Zn RF). Day 20 pup plasma and liver Zn concentrations in the 10 Zn groups were lower than in the 50 Zn groups. In a parallel experiment, rhesus monkeys were fed a Zn-adequatead libitum diet (100 μg Zn/g) or a marginal Zn diet (4 μg Zn/g diet; MZD) throughout gestation and lactation. Day 30 monkey infant plasma and liver Zn levels were similar in the MZD and control groups. Rat brain and monkey brain cortex weights were similar among the dietary groups. The amount of myelin recovered (mg protein/g brain) from day 20 rat pups from the 10 Zn groups was lower than that recovered from the 50 Zn rat pups. Myelin recovery from the MZD and control monkey infants was similar. When myelin protein profiles were characterized, it was found that the percentages of high-molecular-weight (HMW) proteins and Wolfgram protein were higher, whereas the percentages of small and large basic proteins were lower in myelin from the 10 Zn d0 and 50 Zn RF pups compared to the distribution in the 50 Zn AL rat pups. Results for the 10 Zn d0 and 10 Zn d14 pups were similar for all of the parameters studied. The percentage of HMW proteins was higher and that of basic protein lower in myelin from MZD monkey infants compared to the percentage of these proteins in myelin from controls. Although the interpretation of the rat data is complicated because of the anorexia associated with the Zn deficiency, the observed changes in monkey myelin protein profiles provide strong evidence that maternal Zn deficiency affects myelination in the offspring.     

A critical period for formation of secondary myotubes defined by prenatal undernourishment in rats

Rats fed a restricted diet during gestation and lactation gave birth to pups with about 60% the normal birthweight. Maintaining the undernutrition after birth reduced the rate of growth of the pups so that their body weights were only 40% of control at PN7. Soleus and lumbrical muscles in these animals had reduced numbers of muscle fibres, and quantitative examination of embryonic muscles revealed that this was due solely to a decreased formation of secondary myotubes; the number of primary myotubes remained normal. Undernutrition did not affect the number of motoneurones surviving normal developmental death. Restoration of normal dietary intake on E21, one day before birth, did not correct the deficit in muscle fibre numbers in soleus muscles examined when the animals reached one month of age. Development of the lumbrical muscle lags behind the soleus and unrestricted feeding from E21 onwards allowed a normal number of fibres to develop from this time on, although the initial deficit was never restored. These experiments define a critical period in muscle development during which the potential maximum number of secondary myotubes is determined.     

Effects of marginal zinc deficiency on microtubule polymerization in the developing rat brain

One of the possible mechanisms that has been proposed to underlie the deleterious effects of zinc deficiency on brain development is an impairment in the normal formation of the cytoskeletal network. In the current study, in vivo microtubule polymerization was characterized in brain supernatant fluids, from 20-d-old pups whose dams were fed diets containing control (50 micrograms zinc/g) or marginal levels of zinc (10 micrograms zinc/g) throughout pregnancy and lactation. Pup brain and body weights were similar between the groups; however, plasma zinc concentrations were lower (27%) in pups fed the marginal zinc diet than in controls. Tubulin concentrations in 100,000 g brain supernates were similar between the groups; however, tubulin polymerization in the brain supernates was significantly lower in pups fed the marginal zinc diet compared to controls. Primarily, the early events of polymerization were affected; the lag period of the reaction was doubled, and the initial velocity was slower (26%) in supernates from pups fed the marginal zinc diet than in controls. These findings support the idea that some of the negative effects of marginal zinc deficiency on brain development and function may be mediated by an alteration in microtubule formation.     

Neurological Mutation Characterized by Dysmyelination in NCTR-Balb/C Mouse with Lysosomal Lipid Storage Disease

Abstract: Morphological and biochemical studies were performed on the CNS of neurologically affected NCTR Balb/C mouse. Histological and electron microscopic techniques demonstrated severe myelin deficiency in the affected brains. Neither the presence of lipid-containing macrophages nor reactive gliosis was apparent. Analysis of myelin-associated lipids and proteins revealed prominent depletion of galactocerebroside, sulfatide, and proteolipid proteins. In contrast to the scarcity of myelin specific constituents a marked accumulation of G_M2 and G_M3 gangliosides and several neutral glycolipids, i.e., glucocerebroside, lactosylceramide, gangliotriaosylceramide, and gangliotetraosylceramide were found in affected CNS. These abnormalities were already apparent in 12-day-old pups as well as in 65-day-old mice. A significant deficit in the proportion of long-chain fatty acids (C₂₄), notable in both normal and α-hydroxy acids of cerebrosides from affected white matter, was measured. The lack of reactive gliosis, the observed depletion of galactocerebroside and sulfatide at the early age of 12 days, and the relative decrease in long-chain fatty acids in affected CNS strongly suggest a defect in myelinogenesis in this mutant rather than a secondary process of myelin breakdown.     

Effect of dietary protein and calorie deficiency on tryptophan levels in the developing rat brain

The pattern of development of brain tryptophan in the rat was studied in the progeny of mothers fed a 7.5% protein diet ad lib., a 20% protein diet ad lib. and those fed a 20% protein diet pair-fed with mothers who received the 7.5% protein. The pattern of development was similar in all three groups. Starting with a high brain tryptophan content at birth, all animals showed a progressive reduction during the next 3 weeks. However, tryptophan levels at birth were several fold higher in the brains of pups born to mothers receiving either the low protein diet fed ad lib. or those born to mothers who received the 20% protein diet in restricted amounts. From the 14th day after birth, tryptophan concentration of brain in undernourished pups was significantly lower until the 35th day. The implications of this finding are discussed.