Expression of acidic fibroblast growth factor mRNA in the developing and adult rat brain.

We have localized acidic fibroblast growth factor (aFGF) mRNA in the developing and adult rat brain using in situ hybridization histochemistry. Prenatally, hybridization to aFGF mRNA was observed throughout the brain, with the strongest signal associated with cells of the developing cortical plate. Postnatally, labeling was localized to specific neuronal populations. In the hippocampus, labeling of the pyramidal cell layer and dentate granule cells was observed and became progressively more intense with maturation. Labeling was also observed in both the external and internal granule cell layers of the developing cerebellum. Pyramidal cells of the neocortex as well as neurons of the substantia nigra and locus ceruleus also express aFGF. This pattern persists into adulthood, although the intensity of the labeling is significantly reduced in the adult brain. These patterns of hybridization correlate with specific developmental events and suggest that aFGF plays a significant role in both central nervous system development and neuronal viability in the adult brain.     

Subependymal glycosaminoglycan networks in adult and developing rat brain

Histochemical studies of normal adult rat brain indicate two types of glycosaminoglycans in the subependymal region of the lateral ventricle. One network is characterized by an affinity for the cationic dyes alcian blue, aldehyde fuchsin and colloidal iron. These reactions occur at pH 1.0 and at 0.5-0.3 M concentration of MgCl2, which suggests that this material is chondroitin sulfate. The other system is identified by metachromasia with toluidine blue and a loss of PAS staining following sulfation. These findings are consistent with non-sulfated and non-anionic acid mucopolysaccharides. In developing rat brain the differential development of these networks enhances their separate identity. The metachromatic network is present at least by the 10th postnatal day but the polyanionic electrolytes cannot be identified until the 16th to the 22nd days. The possible functional importance of these systems is discussed.     

Subependymal glycosaminoglycan networks in adult and developing rat brain

Summary Histochemical studies of normal adult rat brain indicate two types of glycosaminoglycans in the subependymal region of the lateral ventricle. One network is characterized by an affinity for the cationic dyes alcian blue, aldehyde fuchsin and colloidal iron. These reactions occur at pH 1.0 and at 0.5–0.3 M concentration of MgCl₂, which suggests that this material is chondroitin sulfate. The other system is identified by metachromasia with toluidine blue and a loss of PAS staining following sulfation. These findings are consistent with non-sulfated and non-anionic acid mucopolysaccharides. In developing rat brain the differential development of these networks enhances their separate identity. The metachromatic network is present at least by the 10th postnatal day but the polyanionic electrolytes cannot be identified until the 16th to the 22nd days. The possible functional importance of these systems is discussed.     

Enzymes in intracellular organelles of adult and developing rat brain

Eighty percent of the hexokinase and about a half of the lactate dehydrogenase, pyruvate kinase, and aldolase activities of adult rat cerebral homogenates is particulate, associated to a large extent, with the sediment (P₂) obtained by centrifugation at 17,000g. Centrifugation of P₂ into sucrose gradients shows that all four enzymes are associated with synaptosomes: their peak concentration coincides with that of glutamate decarboxylase rather than with those of mitochondrial enzymes, glutamate dehydrogenase, and aspartate aminotransferase. After hypoosmotic shock and high-speed centrifugation considerable portions of synaptosomal enzymes are recovered in the supernatant phase; the composition of this fluid, as indicated by the higher specific activity of several enzymes, is different from that of the soluble fraction of whole homogenates.The concentration of the seven enzymes studied is considerably lower in fetal than in adult brain and, in general, a larger fraction of the total is soluble. Preferential accumulation with age in the particulate fraction is especially striking in the case of hexokinase. Between fetal and adult life there are changes in the enzymic composition as well as increases in the amount of the total protein attributable to the synaptosomal fraction. Glutamate decarboxylase and lactate dehydrogenase are the synaptosomal enzymes to rise first (before or at birth), followed by hexokinase and, in the third postnatal week, by aldolase and pyruvate kinase. The upsurge of mitochondrial enzymes (that of glutamate dehydrogenase at term and of aspartate aminotransferase 10 days later) is accompanied by insignificant or small increases in the total protein content of the same fraction. The results indicate that the maturation of subcellular organelles involves a stepwise enrichment with various enzymes; some signs of biochemical differentiation precede and others coincide with the development of cerebral functions known to occur in 2- to 4-wk-old rats.     

The turnover of myelin phospholipids in the adult and developing rat brain

1. Inorganic [(32)P]phosphate, [U-(14)C]glycerol and [2-(14)C]ethanolamine were injected into the lateral ventricles in the brains of adult rats, and the labelling of individual phospholipids was followed over 2-4 months in both a microsomal and a highly purified myelin fraction. 2. All the phospholipids in myelin became appreciably labelled, although initially the specific radioactivities of the microsomal phospholipids were somewhat higher. Eventually the specific radioactivities in microsomal and myelin phospholipids fell rapidly at a rate corresponding to the decline of radioactivity in the acid-soluble pools. 3. Equivalent experiments carried out in developing rats with [(32)P]phosphate administered at the start of myelination showed some persistence of phospholipid labelling in the myelin, but this could partly be attributed to the greater retention of (32)P in the acid-soluble phosphorus pool and recycling. 4. It is concluded that a substantial part of the phospholipid molecules in adult myelin membranes is readily exchangeable, although a small pool of slowly exchangeable material also exists. 5. A slow incorporation into or loss of labelled precursor from myelin phospholipids does not necessarily give a good indication of the rate of renewal of the molecules in the membrane. As presumably such labelled molecules originate by exchange with those in another membrane site (not necessarily where synthesis occurs) it is only possible to calculate the turnover rate in the myelin membrane if the behaviour of the specific radioactivity with time of the phospholipid molecules in the immediate precursor pool is known.     

Synthesis and turnover of cerebroside sulfate of myelin in adult and developing rat brain

The turnover of cerebroside sulfate (sulfatide) was followed in both microsomal and myelin fractions of developing and adult rat brains after an intracerebral injection of Na(2)(35)SO(4). In the adult rats, the specific radioactivity of sulfatide of the microsomal fraction reached a maximum 12 hr after the injection, and after 3 days it was reduced to less than 30% of the maximum. In contrast, the specific radioactivity of the myelin sulfatide did not reach a peak until 3 days after the injection and remained essentially at the same level for as long as 6 months. In the case of 17-day-old rats, the specific radioactivity of myelin sulfatide reached a maximum level around 12 hr after the injection and then appeared to decline. The decline was most marked 2-6 days after the injection, suggesting an apparently rapid turnover of myelin sulfatide. When a correction was made for deposition of newly formed sulfatide, the results indicated that the turnover of myelin in the developing animals was also relatively slow. In vitro experiments with purified myelin and 3'-phosphoadenosine-5'-[(35)S]phosphosulfate showed that myelin does not catalyze the galactocerebroside sulfotransferase reaction. This enzyme was found mainly in the microsomal fraction. In vivo studies suggested that a transfer of sulfatide molecules from the endoplasmic reticulum to myelin might occur. In order to obtain direct evidence for such a transfer, rat brain slices after pulse labeling with Na(2)(35)SO(4) were washed free of the isotope and reincubated with nonlabeled Na(2)SO(4). The specific radioactivity of the microsomal sulfatide declined, with a concomitant rise in the specific radioactivity of the myelin sulfatide. These observations are therefore consistent with the postulate that myelin sulfatide is probably synthesized in the endoplasmic reticulum.     

Proteolipids in developing rat brain

In this report data are summarized on changes in the quantity of proteolipid protein (PLP), its amino acid composition, and the lipid moiety of these lipid-protein complexes in rat brain during postnatal development. In all three parts of the central nervous system (CNS) studied (cerebral hemispheres, medulla oblongata and spinal cord) the main pattern of PLP accumulation is on the whole similar. PLP content is very low in the newborn, and it increased 12 to 20-fold during development. The highest rate of PLP accumulation is observed in the periodfrom 10 to 30 days after birth. Against the background of general similarity the concentration of some amino acids such as lysine, proline, tyrosine in PLP somewhat increased during development, while that of aspartic acid, glutamic acid, glycine, and leucine decreased. Soluble proteolipid complexes, purified to various degree from lipids were isolated from brain of rats of different ages. As compared with the original lipid extracts from which they were obtained, the crude and especially purified proteolipids in all the animals studied were enriched in acidic phospholipids (PhL). This prevalence of acidic PhL increased with age. During the development in phospholipid moiety of proteolipids (PL) the content of phosphatidyl serine, sphingomyelin and mainly diphosphatidyl glycerol increases and that of phosphatidyl inositol and especially phosphatidyl choline decreases. The concentration of acidic PhL more tightly bound with PLP appreciably increases with age. Most of these changes occur mainly during the second decade after birth.Special Issue dedicated to Dr. Eugene Kreps.     

Molecular forms of sucrose extractable and particulate acetylcholinesterase in the developing and adult rat brain

The activity of acetylcholinesterase in the rat striatum increased considerably during development, while activities in the cerebellum and midbrain increased only slightly. During maturation the activity of butyrylcholinesterase increased in all the brain regions examined except in cerebellum. The percentage of acetyl-cholinesterase extractable by isotonic sucrose solution from mature striatum was much smaller than those obtained for other regions of the rat brain. For the developing striatum, the percentage of isotonic sucrose extractable activity was almost three times that for adult striatum. Density gradient centrifugation showed that the membrane-bound particulate fraction of adult rat brain was mostly composed of the 10 S form of acetylcholinesterase with little activity of 4 S form of the enzyme. However, a much higher proportion of the 4 S form was found in the isotonic sucrose soluble fraction. In contrast to the particulate fraction from adult brain, that from 6-day old rats contained a much higher proportion of the 4 S form of the enzyme. The sucrose soluble fraction from 6-day old rat brains contained in general much smaller proportion of 4 S form as compared to those from adult rat brains.     

Accumulation and turnover of the classical Folch-Lees proteolipid proteins in developing and adult rat brain.

The turnover of classical Folch-Lees proteolipid proteins was studied after administration of [2,3-3H]tryptophan to both developing and adult rat brain. The animals were killed from 2h to 250 days after subcutaneous injections of [3H]tryptophan. The measured specific radioactivity in developing brain attained maximum value 24h after the administration of label, whereas the total radioactivity per brain reached a maximum 21 days after injection. The half-life of proteolipid protein from the measured specific radioactivity was 7-20 days, depending on the time-points used for the calculation, whereas calculation from total radioactivity between 28-77 and 91-257 days gave half-lives of 35-40 and 188 days respectively. In contrast, in animals injected at 40 days of age, the half-life from the whole-brain-radioactivity data was 188 days. The problem of the recycling of radioactivity for the synthesis of myelin proteins from either a general or a discrete amino acid pool is discussed.     

Endocrine functions of brain in adult and developing mammals

The main prerequisite for organism’s viability is the maintenance of the internal environment despite changes in the external environment, which is provided by the neuroendocrine control system. The key unit in this system is hypothalamus exerting endocrine effects on certain peripheral organs and anterior pituitary. Physiologically active substances of neuronal origin enter blood vessels in the neurohemal parts of hypothalamus where no blood-brain barrier exists. In other parts of the adult brain, the arrival of physiologically active substances is blocked by the blood-brain barrier. According to the generally accepted concept, the neuroendocrine system formation in ontogeny starts with the maturation of peripheral endocrine glands, which initially function autonomously and then are controlled by the anterior pituitary. The brain is engaged in neuroendocrine control after its maturation completes, which results in a closed control system typical of adult mammals. Since neurons start to secrete physiologically active substances soon after their formation and long before interneuronal connections are formed, these cells are thought to have an effect on brain development as inducers. Considering that there is no blood-brain barrier during this period, we proposed the hypothesis that the developing brain functions as a multipotent endocrine organ. This means that tens of physiologically active substances arrive from the brain to the systemic circulation and have an endocrine effect on the whole body development. Dopamine, serotonin, and gonadotropin-releasing hormone were selected as marker physiologically active substances of cerebral origin to test this hypothesis. In adult animals, they act as neurotransmitters or neuromodulators transmitting information from neuron to neuron as well as neurohormones arriving from the hypothalamus with portal blood to the anterior pituitary. Perinatal rats—before the blood-brain barrier is formed—proved to have equally high concentration of dopamine, serotonin, and gonadotropin-releasing hormone in the systemic circulation as in the adult portal system. After the brain-blood barrier is formed, the blood concentration of dopamine and gonadotropin-releasing hormone drops to zero, which indirectly confirms their cerebral origin. Moreover, the decrease in the blood concentration of dopamine, serotonin, and gonadotropin-releasing hormone before the brain-blood barrier formation after the microsurgical disruption of neurons that synthesize them or inhibition of dopamine and serotonin synthesis in the brain directly confirm their cerebral origin. Before the blood-brain barrier formation, dopamine, serotonin, gonadotropin-releasing hormone, and likely many other physiologically active substances of cerebral origin can have endocrine effects on peripheral target organs—anterior pituitary, gonads, kidney, heart, blood vessels, and the proper brain. Although the period of brain functioning as an endocrine organ is not long, it is crucial for the body development since physiologically active substances exert irreversible effects on the targets as morphogenetic factors during this period. Thus, the developing brain from the neuron formation to the establishment of the blood-brain barrier functions as a multipotent endocrine organ participating in endocrine control of the whole body development.     

Sialyltransferases of developing rat brain

The activity of four different sialyltransferases acting on N- or O-linked chains of glycoproteins was studied in brains of 19 days-old embryos, 1 day-old newborns and adult rats. By using asialofetuin, fetuin andN-acetyllactosamine as acceptors, it has been possible to measure independently the following enzyme activities: CMP-NeuAc:Gal1-3GalNac (2–3)-sialyltransferase (EC 2.4.99.4), CMP-NeuAc:Gal1-4GlcNAc (2–3)-sialyltransferase (EC 2.4.99.6), CMP-NeuAc:Gal1-4GlcNAc (2–6)-sialyltransferase (EC 2.4.99.1) and CMP-NeuAc:NeuAc2-3Gal1-3GalNac (2–6)-sialyltransferase (EC 2.4.99.7). The specific activity of the first three enzymes which act on asialylated acceptors showed a 2.6-fold decrease in a parallel manner after ontogenic development, while the activity of NeuAc2-3Gal1-3GalNac (2–6)-sialyltransferase was four times lower in adult than in embryonic brain, showing a stronger dependence on ontogenic development. Despite the higher level of sialyltransferases able to act on glycoproteins, in fetal brain these glycoproteins do not contain a higher amount of sialic acid.Abbreviations HPLC high performance liquid chromatography - N-CAM neural cell adhesion molecule