CHANGES IN POLYSOMES OF THE DEVELOPING RAT BRAIN

Abstract— Rat brain polysomes were prepared from a deoxycholate-treated postmito-chondrial supernatant in the presence of 2% bentonite and 1 mg/ml of yeast RNA to prevent partial degradation during preparation.

• 1 The polysomal preparations had an absorption maximum at 260 mμ and an absorption minimum at 235 mμ. The ratio of absorption maximum to minimum and the RNA to protein ratio were 1·58 and 1·06 respectively in 6-day-old rat brain polysomes. The sedimentation patterns showed six distinct peaks with sedimentation coefficients of 235S, 185S, 173S, 135S, 100S and 80S, indicating that these preparations have the characteristics of pure heavy polysomes.

• 2 The rate of [¹⁴C]phenylalanine incorporation into brain polysomal protein was maximal at approximately 10 days of age and decreased thereafter. A similar progressive reduction with increasing age was found in the stimulation of phenylalanine incorporation by the addition of 60 μg/tube of polyuridylic acid. However, the incorporation of phenylalanine into young rat brain polysomes was usually greater even with the addition of polyuridylic acid than in the older animals.

• 3 The comparative studies on sucrose density gradient centrifugation of polysomes between young and adult rat brains showed a considerable decrease of heavy polysomes in the older animals.

• 4 The effect of various factors on the stability of brain polysomes from both ages has been studied. The rates of RNA, protein and acid-soluble phosphorus release from polysomes of the adult rat brains were usually greater in the presence of high salt concentration, ethylenediaminetetra-acetic acid and urea than those from the corresponding preparations of younger animals. On the basis of evidence obtained from the above results it suggested that the adult brain polysomes were more unstable than those of younger animals.

• 5 The amount of polysomal RNA linearly increased up to the first 20 days after birth and then levelled off. The ratio of G + C/A + U of polysomal RNA was less in the young rat brains, falling to 1·30 as compared to 1·50 in older animals. The differences were statistically significant at less than a 1% level of confidence.

• 6 Polysomal preparations also contained RNase, phosphomonoesterase, phospho-diesterase and 5′-nucleotidase activities which cannot be washed off. The specific activities of these enzymes were generally higher in young rat brains than those in the adult.

     

CHANGES OF THYMIDINE KINASE IN THE DEVELOPING RAT BRAIN

Abstract— Thymidine kinase (ATP: thymidine-5'-phosphotransferase EC 2.7.1.21) of the supernatant fraction from 6-day-old rat brain possessed a pH optimum of 8.0 and required the presence of 5mM-ATP and 2.5 mM-MgCl₂ for maximum activity. The activity was completely inhibited by addition of 1.8 mM-TTP. The enzyme activity was lost if the same supernatant fraction was refrozen and thawed. K_m was 2.8 × 10⁻⁶ M for [6-³H]thymidine.
Following subcellular fractionation of rat brain, the greatest proportion and highest specific activity of thymidine kinase was found in the supernatant fraction. Thymidine kinase activities reached a maximum at 6 days of age and then dropped sharply during maturation. Comparative studies of thymidine kinase activities of cerebrum, cerebellum and the remainder of the brain during growth indicated that the activity in the cerebellum was usually higher than those in the cerebrum and the remainder, and the biggest differences obtained at 6 days after birth corresponded with the peak in cerebellar activity.     

TAURINE IN DEVELOPING RAT BRAIN: CHANGES IN BLOOD-BRAIN BARRIER

Abstract— The fate of [³⁵S]taurine injected intraperitoneally or intracranially has been compared in rats throughout neonatal development. The amount of [³⁵S]taurine present in the whole rat pup 24 h after intraperitoneal injection increases during development to a maximum 15 days after birth, and declines thereafter, whereas the amount of [³⁵S]taurine reaching the brain 24 h after intraperitoneal injection was greatest in the first 5 days after birth. The amount of [³⁵S]taurine remaining in the brain 24 h after intracranial injection does not vary throughout the period of neonatal development. These results suggest that the 'blood-brain' barrier is more accessible to taurine in the first few days after birth than later in neonatal development, and that factors other than simple exchange are involved.     

THE SYNTHESIS OF MYELIN IN DEVELOPING RAT BRAIN

Abstract— —The synthesis of myelin proteins has been studied in the grey and white matter slices of developing rat brain by measuring the incorporation of [³H]lysine and [¹⁴C]arginine into polypeptide. The incorporation was sensitive to cycloheximide and puromycin at 1 mM concentration. Developing rat optic nerve slices, free of retinal ganglion cells, were able to synthesize myelin basic and proteolipid proteins, but rat retinal preparation failed to synthesize myelin basic protein. Rabbit retinae were able to synthesize myelin basic and proteolipid proteins. Significant activity of the myelin marker enzyme 2',3'-cyclic nucleotide-2'-phosphodiesterase has been found in the rabbit retina but not in rat retina. The results presented in this communication suggest that myelin proteins in the rat CNS are synthesized by the oligodendroglial cells and that neurons probably do not participate.     

ADENOSYLMETHIONINE DECARBOXYLASE IN DEVELOPING RAT BRAIN

Adenosylmethionine decarboxylase from rat brain has been found to be similar to the same enzyme isolated from other rat tissues in regard to kinetic parameters, pH optimum, putrescine requirement, and subcellular location. Evidence is presented that pyridoxal phosphate is not the functional cofactor in enzymatic decarboxylation by the rat brain preparation. The capacity for spermidine synthesis in developing rat brain was determined by measurement of the activity of adenosylmethionine decarboxylase. The activity increased dramatically after 10 days of postnatal age. This increase occurred after the period of maximum nucleic acid synthesis, an observation which suggests that spermidine may have a role in the functional development of the brain.     

TRIPHOSPHOINOSITIDE PHOSPHODIESTERASE IN DEVELOPING BRAIN OF THE RAT AND IN SUBCELLULAR FRACTIONS OF BRAIN

Abstract— An assay system for the measurement of triphosphoinositide phosphodiesterase in homogenates of rat brain is described. With triphosphoinositide (TPI) as substrate, and in the presence of 0·1 m -KCI and saturating amounts of diethyl ether, the activity of phosphodiesterase in myelinated brain was 400–500 μmoles of TPI hydrolysed per g wet wt. per hr. One quarter of the adult level of the enzyme was present in rat brain one day after birth, with the remainder being added prior to and during the early stages of myelination. On subfractionation of brain homogenates, substantial activity of the enzyme was located in the soluble portion and in the paniculate fractions enriched in myelin and synaptosomes. The enzyme associated with the particulate fractions could not be detached from the membranes by any of several methods employed. There was a rough correlation between distribution of phosphodiesterase and that of 5'-nucleotidase, an enzyme associated with plasma membrane in a number of tissues. Some implications of the results are discussed.     

THE ACCUMULATION OF ARACHIDONATE AND DOCOSAHEXAENOATE IN THE DEVELOPING RAT BRAIN

—Fatty acids typical of grey matter lipids (C20:4 and C22:6) and of myelin lipids (C20:1 and C24:1) were estimated in developing rat brains. The polyenoic fatty acids (C20:4 and C22:6) are synthesized from the essential fatty acids (C18:2 and C18:3). The results showed that more than 50 per cent of the adult content of the brain polyenoic acids were laid down by day 15. In contrast, the fatty acids characteristic of myelin lipids did not appear in significant quantities until after this time. These findings distinguish biochemically the different periods of brain development associated firstly with cell division (formation of neurons and glial cells) and secondly with myelination. It is of special interest that the period of cell proliferation is accompanied by the appearance in brain lipids of long-chain polyenoic acids derived from the essential fatty acids.     

THE EFFECTS OF HYPERKETONEMIA ON GLYCOLYTIC INTERMEDIATES IN THE DEVELOPING RAT BRAIN

Abstract— Newborn rats from dams fed on a high fat diet developed increased ketonemia and significant hypertriglyceridemia i.e. "hyperketonemic pups". This perinatal metabolic stress led to an alteration in the developmental pattern of glycolytic intermediates in their brains.
In control rats, the concentration of glucose 6-phosphate (G6P) in the brain was high at birth, and gradually decreased to adult values by the third week of life. In contrast, the fructose-1,6-diphosphate (FDP) concentration was low at birth and increased thereafter. The lactate concentration was also high at birth but decreased to the adult level by the first day of life. In the brains of control pups, lactate and pyruvate concentrations remained relatively constant during the first 3 weeks of life.
In the brains of hyperketonemic pups, the concentration of G6P was the same as in the control animals at birth but decreased significantly during the first days of life. During early development the concentrations of FDP and pyruvate were significantly lower and the concentration of lactate, higher in the hyperketonemic pups as compared to the control group. The alteration in the concentration of these glycolytic intermediates in the brains of hyperketonemic pups indicated a change in the developmental pattern of glycolysis. The ratio of [lactate]/[pyruvate] also suggested an increased cytoplasmic redox potential in the brains of hyperketonemic pups during the first week of life.     

THYMIDINE METABOLISM AND DEOXYRIBONUCLEIC ACID SYNTHESIS IN THE DEVELOPING RAT BRAIN

—In growing rat brain, the specific activity of DNA at 12 h after the subcutaneous injection of [³H]thymidine underwent a sharp rise during the first 6 days of life, dropping just as precipitously by 15 days, thereafter continuing to decrease with increasing age. When [³H]thymidine was given to 6-day-old rats, a considerable amount was taken up immediately into the brain. Thymidine taken up into the acid-soluble fraction was readily phosphorylated to its nucleotides, thymidine mono-, di-, and triphosphate (TMP, TDP and TTP) within only 30 min following injection. The highest specific activity was found in TTP. The incorporation of of [3H]thymidine into DNA took place over a longer period of time after injection.     

SYNTHESIS OF RNA IN DEVELOPING RAT BRAIN IN VITRO

—Incorporation of [8-¹⁴C]adenine into a rapidly-labelled fraction of RNA derived from the nucleus, and into a cytoplasmic RNA of high molecular weight was studied in brain slices from new born rats. The kinetic behaviour of the two fractions of RNA was compatible with a precursor-product relationship between them. The change in the specific activity of adenine and the reduction of radioactivity in prelabelled RNA of brain slices in the presence of actinomycin D, suggest that the observed degradation of nuclear RNA is not due to random changes, but is limited to a relatively small fraction, presumably messenger RNA.     

SIALOGLYCOPROTEINS AND SEVERAL GLYCOSIDASES IN DEVELOPING RAT BRAIN

Abstract— The amount of sialoglycoproteins expressed as μmol of sialic acid per g of lipid-free residue remained fairly constant in developing rat brain. However, the activity of various enzymes which may be involved in glycoprotein metabolism varied in an inconstant fashion during the period of development. The specific activity of a neuraminidase increased, N -acetyl-β-glucosaminidase remained relatively constant, while the specific activities of α-mannosidase and α-fucosidase decreased.     

PHOSPHOFRUCTOKINASE AND FUMARATE HYDRATASE IN DEVELOPING RAT BRAIN

The developmental patterns of phosphofructokinase, fumarate hydratase and lactate dehydrogenase were determined and compared using homogenates of rat brain. Phosphofructokinase activity, expressed in terms of tissue wet wt., was relatively constant from 5 days before birth to 8 days postnatal; a 110 per cent increase in activity occurred between 12 and 21 days of age, when adult levels were achieved. The degree of inhibition of phosphofructokinase by 1-0 mM-ATP changed little during development; inhibition by 2-5 mM-citrate was about 50 per cent in both newborn and adult brain. Phosphofructokinase development more closely resembled that of lactate dehydrogenase than that of fumarate hydratase.     

OXIDATIVE PHOSPHORYLATION IN MITOCHONDRIA OF DEVELOPING RAT BRAIN

Abstract—

• 1 Oxygen uptake, ADP/O ratios and respiratory control ratios (RCR) were studied by oxygen electrode techniques in mitochondria prepared from developing rat brain.
• 2 Oxygen consumption, ADP/O ratios and RCR based on mitochondrial protein concentration increased with maturation. Of the substrates employed, succinate supported oxygen uptake best and malate poorest.
• 3 The addition of exogenous NAD to the mitochondrial preparation had no effect on rate of oxygen uptake.
• 4 Lack of change in ADP/O ratio in the presence of glucose, a tricarboxylic acid cycle intermediate (α-oxoglutarate), and ATP leads us to believe that there is no significant hexokinase activity in this preparation.

     

HISTAMINE AND MAST CELLS IN DEVELOPING RAT BRAIN

The number and distribution of mast cells in rat brain were determined at different postnatal ages. The number of brain mast cells was found to change during ontogenic development following the same pattern as brain histamine (HA) levels. The calculated HA content of brain mast cells was close to the HA content of the crude nuclear fraction at every age studied. Since most of the brain HA in the newborn sediments with the crude nuclear fraction, these results suggest that the developmental pattern of brain HA reflects changes in the number of brain mast cells, that is, in the size of the mast cell HA pool. The HA content of the supernatant of the crude nuclear fraction corrected for mast cell HA contamination, on the other hand, follows a developmental pattern similar to that of other known neurotransmitters.     

EFFECT OF UNDERNUTRITION ON AMINO ACID COMPARTMENTATION IN THE DEVELOPING RAT BRAIN

—Rat pups undernourished through 21 days of age show abnormal patterns of cerebral amino acid metabolism. The pattern of incorporation of radioactivity from l -[U-¹⁴C]leucine into amino acids derived from tricarboxylic acid cycle intermediates was altered, with significantly more ¹⁴C being incorporated into glutamate and aspartate in the underfed rats than in controls. Glutamate compartmentation, manifested in the ratio of specific radioactivities of glutamine to glutamate, developed more slowly in the. diet-restricted group. These results are similar to those seen in neonatally-thyroidectomized rats and suggest decreased growth of neuronal processes. This impairment of amino acid metabolism returns to normal after a 7-week period of adequate nutrition.     

INTERRELATIONS BETWEEN POLYAMINES AND NUCLEIC ACIDS: CHANGES OF POLYAMINE AND NUCLEIC ACID CONCENTRATIONS IN THE DEVELOPING RAT BRAIN

The rat brain concentrations of protein, RNA, DNA, putrescine, and of the polyamines spermidine and spermine, were studied during development. Putrescine formation is apparently controlled by ornithine decarboxylase. Spermidine and spermine concentrations change in inverse directions to their anabolic enzymes. It has been presumed, therefore, that the low concentrations of the polyamine-synthesizing enzymes in immature brain are compensated for, by high putrescine and S-adenosylmethionine concentrations. In agreement with previous findings for fish brain, the changes in RNA and spermidine concentrations were most closely correlated. The functions of DNA: spermine are directly correlated only during the periods of brain maturation, after cell proliferation has nearly ceased.     

THE METABOLISM OF TRITIATED DOPAMINE IN REGIONS OF THE RAT BRAIN IN VIVO—II

Abstract— The levels of tritiated catecholamines and metabolites were measured in regions of the rat brain at intervals after the intraventricular injection of [³H]dopamine, [³H]nor-adrenaline and [³H]normetanephrine. The disappearance of catecholamines and appearance of metabolites with time and the regional turnover rates of these amines indicate that the major pathway of the metabolism of noradrenaline and dopamine actively released from physiological storage sites is to the neutral alcoholic metabolites. The acid metabolites, homovanillic acid and 3,4-dihydroxyphenylacetic acid appear to be only minor products of normal dopamine metabolism in rat brain regions including the striate, but are the main end products of the metabolism of excess exogenous dopamine.
The active metabolism of stored noradrenaline to alcohol metabolites is also indicated by the increase in neutral alcohol metabolites accompanying the increased noradrenaline turnover when rats were subjected to electroshock stress. Therefore in the rat brain, neutral alcohol metabolites of dopamine and noradrenaline have great significance in the study of physiological catecholamine turnover in any region.