THE DESMOSTEROL REDUCTASE ACTIVITY OF RAT BRAIN DURING DEVELOPMENT1

Abstract— The reduction of desmosterol by cell-free preparations from developing rat brain was established and the age-dependent alterations in reductase activity were correlated with levels of desmosterol in brain. An increase in enzymic activity followed closely the sharp increase in levels of desmosterol that was observed at about 5 days of age and that reached a maximum at 8-11 days of postnatal age. Furthermore, the abrupt decrease in the desmosterol content of brain at 13-15 days of age was associated with a decrease in enzymic activity. We suggest that the enzyme may be substrate-induced and that this attribute may be of significance with respect to the ontogenesis of myelin. Cerebral desmosterol reductase exhibited a specific requirement for NADPH and was primarily a particulate enzyme.     

THE POSTNATAL DEVELOPMENT OF CATECHOL-O-METHYL TRANSFERASE IN THE RAT BRAIN

Abstract— The postnatal development of three enzymes in the rat forebrain was studied. When expressed per tissue weight the catechol- O -methyl transferase (COMT) increased 2-fold from birth to adult age, the lactate dehydrogenase (LDH) 4-fold and the monoamine oxidase (MAO) 12-fold. Expressed per mg protein the increase in the enzyme activities in the subcellular fractions which contained the main part of the different enzymes was still 2–4-fold for COMT and LDH while for MAO it was 4-fold.
There was a relative increase in the COMT activity in the P₂ fraction (synaptosomes and mitochondria). This increase was identical with a corresponding increase in LDH activity and protein and was probably due to growth of nerve terminals. The COMT in the cytoplasm of the synaptosomes showed the same increase relative to the proteins as did the 'free' cytoplasmic enzyme.
The conclusion is drawn that the enzymes in the rat brain show a certain degree of development during brain growth. An additional increase of some enzymes is due to the development of specialized structures such as mitochondria and nerve terminals with synapses. COMT is not related to any such specialized structure.     

GLYCOPROTEIN CHANGES DURING THE DEVELOPMENT OF HUMAN BRAIN

Brain glycoprotein sugars were studied during human brain development. Marked changes were found in the sugar content of glycopeptides derived from soluble and insoluble glycoproteins, showing a general decrease in the soluble and an increase in the insoluble fraction. The data indicate that changes in glycan moiety and/or in glycoprotein population occur during development. The existence of a‘critical period’in glycoprotein development which coincides with the formation of axonal and synaptic membranes sprouting has been established (Dobbing , 1971).     

CHOLINE ACETYLTRANSFERASE ACTIVITY OF HUMAN BRAIN TISSUE DURING DEVELOPMENT AND AT MATURITY

Abstract— (1) On analysis of human brain tissue to determine its choline acetyltransferase (ChAc) content the recovery of enzyme from many regions is very poor when the tissue is acetone-dried and then extracted in the standard manner; for this reason the method is unsuitable when quantitative recoveries are required; it is preferable to prepare sucrose homogenates and activate these with ether before incubation.
(2) From measurements made on homogenates of one adult brain the highest concentration of ChAc was found in the putamen and the lowest in the corpus callosum. The caudate nucleus also had a high activity. As in other mammals, the concentration of enzyme in the cerebellum was found to be low. Analogous results were obtained on a nine-year-old brain but the level of ChAc activity was generally higher than in the older brain.
(3) During foetal development up to thirty-two weeks, ChAc is higher in the cerebellum than in the caudate, the thalamus, corpora quadrigemina, medulla and spinal cord. In all regions the concentration and total amount of enzyme rise fairly steadily up to this time; between 24 and 32 weeks, however, its concentration in the cerebellum and corpora quadrigemina falls slightly although the total increases considerably.
(4) Comparison of the results with the data of other authors indicates general agreement between the distribution of the enzyme in the human brain and its distribution in other mammals, especially the rhesus monkey. The corpus callosum may be an exception since in man it contains little ChAc while in lower mammals it seems to have relatively high concentrations of both ACh and ChAc.
(5) In comparing the values for ChAc reported here with the values for AChE reported by others, three tissues, the globus pallidus, substantia nigra and cerebellum are found to be exceptional in that relative to their concentration in the caudate the activity of ChAc is only about one-tenth that of AChE.     

LEVEL AND AMINO ACID ACCEPTOR ACTIVITY OF MOUSE BRAIN tRNA DURING NEURAL DEVELOPMENT

Abstract— The level of tRNA in mouse brain tissue was measured at various stages of postnatal development. The amount of tRNA per unit of brain wet weight was little, if at all, altered during the first 22 days after birth and decreased by 26 and 32 per cent by 56 days and maturity, respectively. On a DNA or cellular basis, there was no maturation-dependent decrease in tRNA content. The total amino acid acceptor activity of tRNA for seven different amino acids was measured during neural development. There were considerable differences in the tRNA acceptor activities of individual amino acids within an age group; however on a DNA basis, there was little difference between tRNA preparations obtained from newborn and adult mouse brain tissue. The in vivo levels of aminoacylated-tRNA for the seven amino acids of interest, were measured in brain tissue of 1–, 9–, 34, 70–day-old and adult (over 9 months old) mice. Alterations in tRNA level, total tRNA acceptor activity, for each amino acid, and the levels of in uivo aminoacylation of tRNA were shown to be independent of developmental alterations in brain amino acid pool sizes. The results are discussed with regard to the availability of cellular amino acids for translational events during early mammalian brain development.     

GLYCOSYL TRANSFERASE ACTIVITY IN NORMAL AND SCRAPIE-AFFECTED MOUSE BRAIN

—The conditions required for the optimal activity of several glycosyl transferases were determined in normal and scrapie-affected mouse brain. Particulate preparations were analysed for fucosyl, galactosyl, mannosyl and N-acetyl glucosaminyl transferase activity using endogenous acceptors. Solubilized preparations were analysed for fucosyl, galactosyl and sialyl transferase activity using defined exogenous acceptors. The activity of each of these enzymes was followed at intervals throughout the development of scrapie in the mouse. In the endogenous system no change was found in the fucosyl and mannosyl transferase activities of the scrapie material, but the levels of galactosyl and N-acetyl glucosaminyl transferase began to rise as clinical signs of scrapie developed i.e. at 15–16 weeks post-inoculation. In the exogenous system the levels of galactosyl and fucosyl transferase began to rise in the scrapie material at 11–12 weeks post-inoculation, rising to twice the normal value at 18–20 weeks. Sialyl transferase showed no change in activity.     

COMPOSITION OF MOUSE BRAIN MYELIN DURING DEVELOPMENT

Myelin was isolated from the brains of mice at ages of 14, 24, 41, 44, 47, and 182 days and the contents of lipid phosphorus, cholesterol, lipid galactose, alkenyl groups, ethanolamine phosphoglycerides, choline phosphoglycerides, sphingomyelin, and serine and inositol phosphoglycerides were determined. Significant differences in the composition relative to total lipid phosphorus were found in the myelin. At 14 days of age, the myelin had lower relative amounts of cholesterol, galactolipids, alkenyl groups, and ethanolamine phosphoglycerides and a higher relative amount of choline phosphoglycerides.     

CHANGES IN THE PROTEIN COMPOSITION OF MOUSE BRAIN MYELIN DURING DEVELOPMENT

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

THE PRESENCE OF AN α-GALACTOSIDASE IN BRAIN AND ITS ROLE IN THE DEGRADATION OF THE DIGALACTOSYL DIGLYCERIDE OF BRAIN

Abstract— The presence of α-galactosidase activity has been demonstrated in rat brain. This enzyme, located mainly in the crude mitochondrial fraction, actively hydrolysed the substrates p -nitrophenyl-α-galactoside and melibiose, and also catalysed the hydrolysis of digalactosyl diglyceride of both animal and plant origin. The hydrolysis of p -nitrophenyl-α-galactoside, as catalysed by the α-galactosidase, occurred optimally at pH 4·9, showed an approximate K _m of 1·0 × 10⁻³ m , and was markedly inhibited by melibiose, galactose and the mercuric ion.     

RNA POLYMERASE ACTIVITY IN VARIOUS CLASSES OF NUCLEI FROM DIFFERENT REGIONS OF RAT BRAIN DURING POSTNATAL DEVELOPMENT

—The changes in the wet weight and the numbers of cell nuclei recovered from the cerebral hemispheres, the cerebellum and the brain stem of rats from the period of 5–30 days after birth have been determined. In parallel a study has been made of the RNA polymerase activity, both in the unfractionated nuclei from these regions and in the nuclei separated by zonal centrifugation. In general there is a considerable decline in activity during this period, which occurs in all class of nuclei although not to the same extent. The most dense nuclei from the cerebellum retain relatively high activity at 20 days after birth, possibly due to the contribution of the microneuronal nuclei.     

CHANGES IN TITER OF THE BRAIN HORMONE DURING DEVELOPMENT OF THE SILKWORM, BOMBYX MORI

Changes in titer of brain hormone (BH) extracted from the brain, head, and thorax and abdomen during the development of Bombyx mori from the 4th larval molting up to 6 days after adult emergence were investigated. The hypothesis is presented that high secretory activity of the brain is not reflected in a corresponding change in its BH titer, while low secretory activity brings about an accumulation of BH in the brain. An interesting finding is that extremely high titers of BH were found in the thorax and abdomen, from 4 days after pupation to adult emergence, of females only. This sexual difference was, however, not found in all of the races examined.     

THE REGIONAL AND SUBCELLULAR DISTRIBUTION OF CATECHOL-O-METHYL TRANSFERASE IN THE RAT BRAIN

Catechol-O-methyl transferase (COMT) activities determined in different regions of rat brain showed small variations. Highest activities were found in the hypothalamus and corpora quadrigemina, and lowest activities in the hippocampus and corpus striatum. The regional distribution of COMT was thus at variance with the distribution of DOPA decar- boxylase in this study and with the distribution of catecholamines and tyrosine hydroxylase reported in the literature. Determinations of the subcellular distribution of COMT in rat forebrain showed that 50 per cent of the activity was recovered in the high speed supernatant fluid and about 33 per cent in the crude mitochondrial fraction. Further separation of the latter by discontinuous sucrose gradients showed that the particulate COMT was found in the synaptosomal fraction in an occluded form. Full enzyme activity was only obtained after treatment with a detergent or after resuspension in water. After hypo-osmotic rupture of the crude mitochondrial fraction, COMT was recovered in the cytoplasmic fraction. The subcellular distribution of COMT was very similar to the ones of lactate dehydrogenase and DOPA decarboxylase. The proportions of soluble COMT obtained from homogenates of various regions of the brain differed from that of choline acetyl transferase and DOPA decarboxylase but were similar to that of lactate dehydrogenase. In conclusion, COMT is a cytoplasmic enzyme almost evenly distributed in the CNS. Its distribution does not resemble the distributions of the catecholamines or of the enzymes participating in the synthesis of catecholamines.     

ENZYMES OF PHOSPHOINOSITIDE METABOLISM DURING RAT BRAIN DEVELOPMENT

—The activities of four enzymes concerned with inositol lipid metabolism have been determined in homogenates of rat brains of different ages. The enzymes are CDP-diglyceride inositol phosphatidate transferase, phosphatidylinositol kinase, diphosphoinositide kinase and triphosphoinositide phosphomonoesterase. The activities of all the enzymes increased with age. Phosphatidylinositol kinase activity rose most sharply well before myelination, reaching a maximum at about 6 days of age. Diphosphoinositide kinase and triphosphoinositide phosphomonoesterase activities increased most rapidly during myelination. The increase in CDP-diglyceride inositol phosphatidate transferase showed no definite association with any period of development. It is concluded that triphosphoinositide metabolism is associated with myelin or a closely related structure.     

ACETYL-COENZYME A: 1,4-DIAMINOBUTANE N-ACETYLTRANSFERASE: ACTIVITY IN RAT BRAIN DURING DEVELOPMENT, IN EXPERIMENTAL BRAIN TUMOURS AND IN BRAINS OF FISH OF DIFFERENT METABOLIC ACTIVITY

—Acetyl-CoA: 1,4-diaminobutane N-acetyltransferase catalyses the first step of putrescine catabolism in mammalian brain. It may be important in putrescine degradation of other tissues as well. Its specific activity is higher in homogenates of immature than of mature rat brains. A steady decline of putrescine acetylase activity is observed from birth until approx adult levels are reached at day 30. Microsomes and purified nuclei from brains of 2-day-old rats show considerably higher putrescine acetylase activities than the corresponding subcellular organelles from adult brains. Increased putrescine acetylase activities were found in nitroso-ethylurea-induced gliomas, together with a dramatic increase of putrescine concentration. High tissue concentrations of putrescine are, however, not necessarily correlated with enhanced putrescine acetylase activities. In trout brains a linear increase of acetyl-CoA: 1,4-diaminobutane N-acetyltransferase activity was observed together with a decrease of putrescine concentration after adaptation of the animals to increased water temperature.