STRUCTURAL AND BIOCHEMICAL MATURATION OF THE CEREBRAL PALLIUM IN RABBIT FETUSES: MORPHOGENESIS AND LIPIDS

Morphological parameters of maturation of the cerebral pallium in rabbit fetuses ranging between 20 days of gestation (d.g.) and the early neonatal stage are expressed semi-quantitatively and correlated with progressive changes in the brain lipids, glycolipids and nucleic acids. Dual expression of the chemical values, using as referents both the dry weight of the tissue and the DNA unit, reveal the crucial stage in brain development when rapid cell proliferation is replaced by rapid cell growth; this stage in rabbit fetuses occurred between 28 and 30 d.g. Between 20 d.g. and the early neonatal phase the RNA decreased moderately when expressed per unit of DNA. Even at the time of term birth the cortical nerve cells of the rabbit showed signs of immaturity including a relatively small nuclear volume. On the dry weight basis, the lipids of the cerebral pallium exhibited little change in composition during fetal development; however, cerebrosides rose substantially between 30 d.g. and the early neonatal phase. When expressed per unit of DNA, all lipids and glycolipids continued to increase progressively in a pattern characteristic of growth throughout the prenatal period studied. This increase was also apparent when the lipid constituents were expressed per total pallium at the progressive gestational stages. The molar ratios of phospholipids:cholesterol:cerebrosides in the pallium of rabbits of different ages were as follows: in adult rabbits-2.9: 2.6: 1.0, in the newborn-2.9: 1.3: 0.2 and in the 30 d.g. fetuses-3.0: 1.2:0.44. These values reflect the fact that during maturation the content of phospholipids changes little, whereas that of cholesterol and especially erebrosides increases markedly.     

PROTEIN SYNTHESIS BY HIGHLY AGGREGATED AND PURIFIED POLYSOMES FROM YOUNG AND ADULT RAT BRAIN

The state of aggregation and the activity of polyribosomes as well as the activity of the pH 5 enzyme fraction were studied at two stages of postnatal brain development, 9 and 50 days after birth. When the polyribosomes were prepared at 0°C in the presence of 5 mm -Mg²⁺, more than 85 per cent of the polyribosome material exhibited a sedimentation coefficient higher than 110 S. High Mg²⁺ concentrations are, therefore, unnecessary to obtain highly aggregated brain polyribosomes. The basal amino acid incorporating activity of both 9- and 50-day-old rat brain preparations is at least equal to that of rat liver. When prepared by the same procedure as above, 9-day-old rat brain polyribosomes seem to be more active (20 per cent) than those of adult brain. However, this difference in activity depends on the presence of a non-ribosomal inactive contaminant which is always present in higher amounts in adult brain preparations. When purified from this contaminant, the preparations do not differ in activity. High Mg²⁺ concentrations are also not necessary for optimal protein synthetic activity and, in fact, are inhibitory. When assayed with both types of highly aggregated polyribosomes, the pH 5 enzyme fraction from adult brain is clearly less active than that of 9-day-old rats. These results suggest that the loss of brain protein synthesis during development does not depend on the stability of the messenger RNA-ribosome complex but only on the soluble pH 5 enzyme fraction.     

Ontogeny of microsomal activities of triacylglycerol synthesis in guinea pig liver

Because the onset of triacylglycerol-rich lipoprotein synthesis occurs in guinea pig liver during fetal life, we investigated the microsomal enzyme activities of triacylglycerol synthesis in fetal and postnatal guinea pig liver. Hepatic monoacylglycerol acyltransferase specific and total microsomal activities peaked by the 50th day of gestation and declined rapidly after birth to levels that were virtually unmeasurable in the adult. Peak fetal specific activity was more than 75-fold higher than observed in the adult. The specific activities of fatty acid CoA ligase and lysophosphatidic acid acyltransferase increased 2- to 3-fold before birth; lysophosphatidic acid acyltransferase increased a further 2.6-fold during the first week of life. Specific activities of phosphatidic acid phosphatase, microsomal glycerophosphate acyltransferase, and diacylglycerol acyltransferase varied minimally over the time course investigated. These data demonstrate that selective changes occur in guinea pig hepatic microsomal activities of triacylglycerol synthesis before birth. Because of an approximate 11-fold increase in hepatic microsomal protein between birth and the adult, however, major increases in total microsomal activity of all the triacylglycerol synthetic activities occurred after birth. The pattern of monoacylglycerol acyltransferase specific and total microsomal activities differs from that of the rat in occurring primarily during the last third of gestation instead of during the suckling period. This pattern provides evidence that hepatic monoacylglycerol acyltransferase activity probably does not function to acylate 2-monoacylglycerols derived from partial hydrolysis of diet-derived triacylglycerol.     

Compartments of protein metabolism in the developing brain.

We investigated whether the higher rate of amino acid incorporation into immature than into mature brain protein is due to (a) rapid growth, (b) a small rapidly metabolized protein pool, or (c) a higher turnover rate of most of the protein. We measured net growth and the incorporation of [14C]tyrosine or [14C]valine into brain proteins in young rats and mice. The specific activity of the free amino acid pool was kept constant in the tyrosine experiments. Incorporation of tyrosine into protein was continued for up to 30 h by which time the specific activity of protein-bound amino acid reached 1/3 of that of the free (precursor) amino acid. The growth (accretion) of brain proteins was approx. 0.635% per h in mice and rats in the 1-4 day period after birth. In previous studies we found that the turnover rate of the bulk (about 96%) of adult brain proteins is below 0.3% per h. Because of the presence of a small (about 4%) active pool the average turnover rate is 0.6% per h. The present experiments show a degradation rate of 0.7-1.1% per h in the brain proteins of the young. This high metabolic rate is not due to a small rapidly degraded fraction of protein. The very rapid protein fraction previously seen in adult rats is either very small (below 1%) or absent in the young. Thus most of the proteins in the immature brain during the rapid growth phase are formed and broken down at a rate that is approximately three times higher than that of the bulk of proteins in the adult brain. The small active protein pool in the adult on the other hand has a metabolic rate higher than that of the immature brain proteins.     

PROTEIN SYNTHESIS IN FRACTIONS FROM ISOLATED BRAIN CELL NUCLEI

Abstract— 1. The incorporation in vivo and in vitro of isotopically labelled leucine into fractions of nuclear proteins from young and adult rat brain was investigated.
2. During post-natal cerebral maturation, the ability of nuclei from brain cells to synthesize proteins decreased. The specific activities of all the fractions of nuclear protein were highest in 3-day-old rats and declined thereafter. Nuclei from adult brain cells exhibited only 10 per cent of the activity found in nuclei from brain cells of 3-day-old rats.
3. The 'residual protein' fraction was most rapidly labelled, peak activity being reached within 30 min after injection. In vitro , the 'residual protein' fraction attained maximum activity within 40 min.
4. The specific activity of the chromatin acidic proteins (HCl-insoluble) was considerably higher than that of the histones both in vivo and in vitro. Histones were the most inert of all the nuclear protein fractions studied.
The possible functional significance of the various protein fractions during the process of cerebral maturation and in the adult brain is discussed.     

METABOLISM OF HIGHLY BASIC PROTEINS OF RAT BRAIN DURING POSTNATAL DEVELOPMENT

Abstract— (1) The encephalitogenic basic protein obtained from adult rat brain by treatment with 0·03 N-HCl was demonstrable in the brain on the 10th day after birth. It showed a marked increase in quantity during the phase of active myelination.
(2) The proteins extracted under similar conditions from 5-day old rat brain contained several highly basic proteins other than the encephalitogenic basic protein. These basic proteins, which were electrophoretically similar to highly basic proteins extracted similarly from adult rat liver, are histones.
(3) For metabolic studies the entire group of highly basic proteins in the acid extract was obtained after one-step adsorption of other proteins on DEAE-cellulose equilibrated at pH 9·8
(4) After injection of [¹⁴C]lysine the fractions containing highly basic proteins, water soluble non-basic proteins and other tissue proteins of the brain showed higher relative specific radioactivities during the period 1–10 days after birth than during later stages of postnatal development. The fraction containing proteolipid protein, another myelin protein, showed a low relative specific radioactivity throughout the whole period of postnatal development. The relative specific radioactivity of proteolipid protein was somewhat higher in young than in adult rat brain.     

Activities of enzymes of ketone-body utilization in brain and other tissues of suckling rats

1. The activities of 3-hydroxybutyrate dehydrogenase and 3-oxo acid CoA-transferase in rat brain at birth were found to be about two-thirds of those of adult rat brain, expressed per g wet wt. The activities rose throughout the suckling period and at the time of weaning reached values about three times higher than those for adult brain. Later they gradually declined. 2. At birth the activity of acetoacetyl-CoA thiolase in rat brain was about 60% higher than in the adult. During the suckling period there was no significant change in activity. 3. In rat kidney the activities of the three enzymes at birth were less than one-third of those at maturity. They gradually rose and after 5 weeks approached the adult value. Similar results were obtained with rat heart. 4. The activity of glutamate dehydrogenase (a mitochondrial enzyme like 3-hydroxybutyrate dehydrogenase and 3-oxo acid CoA-transferase) also rose in brain and kidney during the suckling period, but at no stage did it exceed the adult value. 5. Throughout the suckling period the total ketone-body concentration in the blood was about six times higher than in adult fed rats, and the concentration of free fatty acids in the blood was three to four times higher. 6. It is concluded that the rate of ketone-body utilization in brains of suckling rats is determined by both the greater amounts of the key enzymes in the tissue and the high concentrations of ketone bodies in the blood. In addition, the low activities of the relevant enzymes in kidney and heart of suckling rats may make available more ketone bodies for the brain.     

Creatine Kinase Activity in Postnatal Rat Brain Development and in Cultured Neurons, Astrocytes, and Oligodendrocytes

The development and distribution of cytosolic creatine kinase (CK) activity was studied in rat brain and in cell culture. The activity of CK in whole brain increased almost fivefold during the period from birth to day 40 when adult levels of 18-19 U/mg of protein were attained. The distribution of CK activity was examined in dissected regions of the adult brain and was nonuniform; the cerebellum, the striatum, and the pyramidal tracts contained significantly higher CK activity than did whole brain. The cellular compartmentation of CK was investigated using primary cultures of purified neurons, astrocytes, and oligodendrocytes. The CK activity in neurons increased fourfold greater than that measured at the time of isolation to 4 U/mg of protein. The CK activity in astrocytes cultured for 20 days was 3.5 U/mg of protein and was 1.5-fold greater than that measured at the time of isolation. In contrast, the CK activity in cultured oligodendrocytes (day 20) was three- to fourfold higher than that determined in astrocytes and almost sevenfold higher than the activity measured at the time the cells were isolated. The high levels of CK in cultured oligodendrocytes suggest a role for this enzyme in oligodendrocyte function and/or myelinogenesis.     

ACTIVITY OF CYCLIC AMP-DEPENDENT MICROSOMAL PROTEIN KINASE AND PHOSPHORYLATION OF RIBOSOMAL PROTEIN IN RAT BRAIN DURING POSTNATAL DEVELOPMENT

Abstract— Microsomes from rat brain exhibited protein kinase activity which was stimulated by cyclic AMP when assayed in the presence of exogenous protein substrate, such as thymus histone. In the absence of exogenous substrate some phosphorylation of microsomal protein occurred, but no stimulation by cyclic AMP could be discerned, probably because of limitations of substrate. The maximal activity of microsomal protein kinase observed in the presence of saturating concentrations of histone and the optimal concentration (5 μ m ) of cyclic AMP remained essentially unchanged from birth to early adulthood, but the magnitude of the stimulation by cyclic AMP was significantly higher at birth than at 30 days of age. Brain ribosomal proteins could be phosphorylated by the cyclic AMP-dependent brain protein kinase. Their total capacity for acceptance of phosphate by means of this phosphorylation reaction remained unchanged throughout the postnatal development of the brain. Our results are consistent with the possibility that phosphorylation of ribosomal protein mediated by cyclic AMP-dependent protein kinase may play a a role in the postnatal regulation of cerebral protein synthesis, as a result of the changes in the levels of cyclic AMP known to occur in brain during postnatal maturation.     

A study of the changes in protein composition of mouse brain during ontogenetic development

Of the total protein in an adult mouse brain, 35 per cent is water-soluble and 65 per cent water-insoluble. Using an extraction scheme of sequential treatment with water, Triton X-100, and sodium lauryl sulphate, it was possible to solubilize at least 90 per cent of this total in distinct groups. Qualitative analysis of the extracts was achieved by electro-phoresis in porosity gradient polyacrylamide gels. In this way, each fraction was resolved into 20-50 protein bands. This sequential extraction-fractionation procedure was employed in a study of the onto-genetic changes in mouse brain proteins. The most pronounced accumulation of protein and alteration of protein composition occurred during the first few weeks after birth. Beyond that period, both quantitative and qualitative changes were much less dramatic, except in the 1 % SLS fraction, which continued to increase in size throughout the mouse's lifespan. Whereas the aqueous-soluble proteins predominated during the very early stages of development, the detergent-soluble constituents accounted subsequently for a steadily increasing proportion of the total protein.     

Changes in the rates of protein synthesis in the brain of goldfish at various temperatures.

Intraperitoneal injections of [¹⁴C] tyrosine suspension into goldfish produced a relatively constant specific activity of free tyrosine in the brain over an 8 hour experimental period. This made the measurement of the rate of cerebral protein synthesis in this time period possible. The increase of protein-bound [¹⁴C] tyrosine was linear with time and occured in most protein fractions. In the absence of a net increase of protein it was an indicator of the rate of cerebral protein turnover. Rates of incorporation of tyrosine into brain proteins were 0.52 per cent/hour at 34° and 0.026 per cent/hour at 10°, i.e., the rate at 34° was about 20-fold that at 10°. Temperature gradients of protein turnover were similar in fish and rat brain.     

IN VITRO BIOSYNTHESIS OF TUBULIN ON TOTAL, FREE AND MEMBRANE-BOUND POLYSOMES FROM THE DEVELOPING RAT BRAIN

Abstract— Incorporation of [³H]leucine into tubulin and total protein was examined using a polysomal system from newborn (1-day-old). young (10-day-old) and adult (3-month-old) rat brains and cerebral cortices. The rate of tubulin biosynthesis (specific radioactivity) was always lower than that of total protein biosynthesis. No significant differences in the specific radioactivities of the synthesized total proteins were found between the newborn and young brain polysomal system, although young cerebral cortical polysomes were less active than newborn cerebral cortical polysomes. The adult brain (or cerebral cortical) polysomes were less active, about 20-30% lower than the young brain (or cerebral cortical) polysomes. The incorporation of [³H]leucine into tubulin showed a progressive decrease in the polysomal systems isolated from the newborn, young and adult rat brains and cerebral cortices. These tendencies were similar in every cell sap taken from newborn, young and adult rat brain homogenates.
In order to examine the relative activities of free and bound polysomes of the developing rat brain in tubulin biosynthesis. double-labelling experiments were carried out. Labelled tubulin was purified by the assembly and disassembly method, followed by SDS gel electrophoresis, or by vinblastine precipitation method, followed by SDS gel electrophoresis; then identification by co-electrophoresis with native brain tubulin, molecular weight determination and demonstration of specific aggregation in the presence of GTP followed. Free and bound polysomes showed approximately similar activities during tubulin biosynthesis. Furthermore, relative activities of tubulin biosynthesis by free and bound polysomes did not significantly change during development.     

Timing of Expression of r and Its Encoding mRNAs in the Developing Cerebral Neocortex and Cerebellum of the Mouse

The expression of tau mRNA and of the corresponding encoded protein variants was studied during postnatal development in two brain regions differing in their timing of differentiation: the cerebral neocortex and the cerebellum. (a) The expression of tau mRNA was different in the two regions. Maximal contents were found at early stages in the cerebral neocortex, with a 10-fold decrease at later stages. In the cerebellum, two peaks of tau mRNA were observed soon after birth and in adulthood, with minimal values at postnatal day 6. (b) The expression of total tau proteins was similar to that of their encoding mRNAs in the cerebral neocortex, i.e., high concentrations after birth and low contents at later stages. In contrast, two peaks of tau proteins were observed in the cerebellum: the first perinatally and the second with a maximum at postnatal day 15. (c) Both in the cerebral neocortex and especially in the cerebellum, increasing concentrations of mature tau variants were expressed at late developmental stages, i.e., when total tau protein contents were decreased. In conclusion, the fluctuations in expression of tau and of its encoding mRNA seen in the cerebellum seem to reflect differences in the timing of differentiation of the various cell types, i.e., the macroneurons and the interneurons, present in this brain region. The adult tau variants appear in both the neocortex and the cerebellum only at late developmental stages, i.e., when most of the circuitry has been established, although these two regions markedly differ in their timing of differentiation.     

Developmental and Regional Studies of the Metabolism of Inositol 1,4,5-Trisphosphate in Rat Brain

Coupling of CNS receptors to phosphoinositide turnover has previously been found to vary with both age and brain region. To determine whether the metabolism of the second messenger inositol 1,4,5-trisphosphate also displays such variations, activities of inositol 1,4,5-trisphosphate 5'-phosphatase and 3'-kinase were measured in developing rat cerebral cortex and adult rat brain regions. The 5'-phosphatase activity was relatively high at birth (approximately 50% of adult values) and increased to adult levels by 2 weeks postnatal. In contrast, the 3'-kinase activity was low at birth and reached approximately 50% of adult levels by 2 weeks postnatal. In the adult rat, activities of the 3'-kinase were comparable in the cerebral cortex, hippocampus, and cerebellum, whereas much lower activities were found in hypothalamus and pons/medulla. The 5'-phosphatase activities were similar in cerebral cortex, hippocampus, hypothalamus, and pons/medulla, whereas 5- to 10-fold higher activity was present in the cerebellum. The cerebellum is estimated to contain 50-60% of the total inositol 1,4,5-trisphosphate 5'-phosphatase activity present in whole adult rat brain. The localization of the enriched 5'-phosphatase activity within the cerebellum was examined. Application of a histochemical lead-trapping technique for phosphatase indicated a concentration of inositol 1,4,5-trisphosphate 5'-phosphatase activity in the cerebellar molecular layer. Further support for this conclusion was obtained from studies of Purkinje cell-deficient mutant mice, in which a marked decrement of cerebellar 5'-phosphatase was observed. These results suggest that the metabolic fate of inositol 1,4,5-trisphosphate depends on both brain region and stage of development.     

Synthesis and regulation of lipoprotein lipase in the hippocampus

Lipoprotein lipase (LPL) expression was determined in adult rat hippocampus and compared to enzyme expression in other brain regions. Hippocampus LPL mRNA levels were at least 2.5-fold higher than those detected in the cerebral cortex, cerebellum, and remaining brain regions. Enzyme mass and activity levels in the hippocampus were also increased to a similar degree. De novo synthesis of LPL in the hippocampus was confirmed by [35S]methionine-labeling of the tissue and identification of a 57 kDa protein obtained by immunoprecipitation. Addition of an excess amount of bovine LPL completely prevented the immunoprecipitation of this protein. The effect of nutritional modulations on brain LPL activity was determined after a 12-h fast. While no significant changes were observed in other regions of the brain, hippocampus LPL activity in fasted rats increased by 60% compared to the fed control group. Simultaneously, fasting reduced adipose LPL activity by 60%. Intraperitoneal injection of ACTH over a 5-day period had no effect on hippocampus LPL activity, while adipose LPL levels increased 2.3-fold and heart LPL levels decreased 1.4-fold. We conclude that LPL is synthesized, active and regulated in a tissue-specific manner in the adult rat hippocampus.     

ONTOGENESIS AND REGIONAL DISTRIBUTION OF HISTAMINE AND HISTAMINE-N-METHYLTRANSFERASE IN THE GUINEA PIG BRAIN1

The ontogenetic development and the regional distribution of histamine (HA) and histamine-N-methyltransferase (HMT, EC 2.1.1.8) in guinea pig brain and pituitary gland were studied. The samples were taken every fourth day beginning on the 28th foetal day. The HA concentration in the brains of the youngest foetuses was almost undetectable. A significant increase in HA concentrations occurred between days 40 and 44, which coincides with the period of rapid growth of nerve cell processes in this species. After this, a steep increase continued to the end of gestation in the hypothalamus, and to a lesser degree in the medulla-midbrain and in the forebrain. In all parts of the brain the adult HA levels were reached by the time of birth. The HMT activity increased 15-fold from the 28th foetal day to the adult and reached ca. 80% of the adult activity by the time of birth. The HMT activity developed earlier in the midbrain than in the forebrain or in the cerebellum, but after the birth the regional distribution of HMT was fairly even. In the pituitary gland the HA concentration and HMT activity increased hundredfold and tenfold, respectively. The developmental patterns of HA and HMT in the guinea pig brain give support to the concept that HA might be a neurotransmitter in the brain.     

DEVELOPMENTAL PROFILES OF GANGLIOSIDES IN HUMAN AND RAT BRAIN

Abstract— The developmental profiles of individual gangliosides of human brain were compared with those of rat brain. Interest was focused mainly on the pre- and early postnatal development. Human frontal lobe cortex covering the period from 10 foetal weeks to adult age and the cerebrum of rat from birth to 21 days were analysed. Lipid-NANA and lipid-P were followed; in the rat, also protein and brain weight. A limited number of samples of human cerebral white matter and cerebellar cortex were also studied. The following major results were obtained:

• 1 The ganglioside concentration increased approximately three-fold within a short period: in rat cerebrum, from birth to the 17th day; in human cerebral cortex, from the 15th foetal week to the age of about 6 months. The largest increase in the rat brain occurred by the 11th to the 13th day; in human brain by term. The relative increase of gangliosides during this period was more rapid than that of phospholipids.
• 2 A hitherto unknown distinct early period of ganglioside and phospholipid formation in rat occurred by the second to fourth day.
• 3 The changes in brain ganglioside pattern, characteristic of the developmental stages of the rat, were found to be equally pronounced in the human brain.
• 4 Regional developmental differences in the ganglioside pattern were demonstrated in human brain. A characteristic white matter pattern, rich in monosialogangliosides, had developed by the age of 1 year. The increase in ganglioside concentration and the formation of the definitive ganglioside pattern of cerebellar cortex occurred later than in cerebral cortex. This cerebellar pattern was characterized by a very large trisialoganglioside fraction.
• 5 The two periods of rapid ganglioside metabolism in rat brain preceded the two periods of rapid protein biosynthesis.

     

A regional study of developing rat brain: The accumulation and distribution of proteolipid proteins

The accumulation and distribution of proteolipid proteins in rat brain and selected brain regions (cerebellum, cerebral cortex, basal ganglia, and hippocampus) were studied during early postnatal development. In whole brain an eightfold increase of proteolipid was observed between ten and 33 days after birth. This was reflected in the separate regions examined where the proteolipid protein content increased six- to ten-fold during the same period. The basal ganglia and cerebral cortex contributed the greatest amount to the total proteolipid present. However, at 28–33 days the greatest concentration (mg/g tissue) was observed in the basal ganglia and hippocampus. When the proteolipid protein preparations were examined by sodium dodecyl sulfate (SDS) polyacrylamide gel electrophoresis, distinctive, heterogeneous patterns for each brain region were obtained. Proteolipid from basal ganglia (the region richest in white matter) consisted primarily of two major protein bands with apparent molecular weights of approximately 21,500 and 26,000. Both of these bands dramatically increased in quantity during myelination, and the larger protein coelectrophoresed with isolated myelin proteolipid protein. Both bands were also found present in proteolipid preparations from the other brain regions but in varying amounts relative to the total. The data suggest that the increase in proteolipid observed during this developmental period was due in large measure to the accumulation of myelin-specific proteolipids, but also that a significant proportion of the increase was due to the accumulation of nonmyelin components.     

ACTIVITIES OF SOME ENZYMES INVOLVED IN HOMOCYSTEINE METHYLATION IN BRAIN, LIVER AND KIDNEY OF THE DEVELOPING RHESUS MONKEY

Abstract— The specific activities of the enzymes responsible for remethylation of homocysteine to methionine. N⁵-methyltetrahydrofolate-homocysteine methyltransferase and betaine-homocysteine methyl-transferase, and of the enzyme responsible for transferring the β-carbon atom of serine to tetrahydrofolate. serine tetrahydrofolate 5,10-hydroxymethyltransferase, have been measured in brain, liver and kidney of the developing Rhesus monkey from mid-gestation, from birth and neonatal life to maturity. The specific activity of N⁵-methyltetrahydrofolate-homocysteine methyltransferase in all tissues is higher during late gestation and shortly after birth than it is in the adult, and in brain and liver it shows a positive correlation with increasing gestational age. Betaine-homocysteine methyltransferase activity is not measurable in brain. In liver it increases linearly during fetal and neonatal development until values found in the adult are reached. In kidney there is a sharp linear increase during the period of gestation studied. The drop at birth is followed by a sharp increase back to values noted at the end of gestation and thereafter a slow increase to values found in the adult. The specific activity of serine-tetrahydrofolate 5,10-hydroxymethyltransferase tends to be higher in fetal and early neonatal brain than it is in adult brain, whereas in liver and kidney it is low in the fetus and rises during development to reach values found in the adult some months after birth.     

Phospholipid exchange activity in developing rat brain

Phospholipid exchange activity has been determined in the supernatant fraction of rat brain from birth through to maturity by measuring the protein-catalysed transfer of total and individual 32P-labelled phospholipids from microsomal membranes to mitochondria, and the transfer of [14C]phosphatidylcholine from liposomes to mitochondria. Transfer activity has also been compared in brain and liver supernatant. Overall phospholipid exchange activity in the brain increased only slightly with age. The activity at birth was 75% of the adult value. However, the transfer of individual phospholipids showed markedly different trends during postnatal brain development. The transfer of phosphatidylinositol (PI) and ethanolamine phospholipids increased postnatally to a maximum at 9 days of age, with lowest values in adult brain. Phosphatidylcholine (PC) transfer increased from 9 days to reach maximum values in the mature brain. The transfer of sphingomyelin was highest immediately after birth. PI transfer activity was higher in brain than liver, while PC and ethanolamine phospholipid transfer activity was higher in liver. The heterogeneity of phospholipid exchange proteins in central nervous system tissue is reflected in the developmental changes in exchange activity towards individual phospholipids. The various exchange proteins appear to have separate induction mechanisms. The presence of exchange-protein activity from birth in the rat indicates the functional importance of phospholipid transport during cell acquisition and membrane proliferation. Activity is not primarily associated with membrane formation such as the formation of the myelin sheath, and therefore is more likely to be involved in the process of phospholipid turnover.