Regulation of Brain and Cerebrospinal Fluid Calcium by Brain Barrier Membranes Following Vitamin D-Related Chronic Hypo- and Hypercalcemia in Rats

Male Fischer-344 rats, 21 days old, were fed diets containing 0 (LOD), 2,200 (CONT), or 440,000 (HID) international units of vitamin D3 per kilogram for 12 weeks. [Ca] was measured in plasma, CSF, brain, and choroid plexus. In addition, 45Ca and 36Cl transfer coefficients (KCa and KCl) for uptake from blood into CSF and brain were determined. Although plasma ionized [Ca]s in LOD and HID rats were 50% and 136%, respectively, of values in CONT animals, CSF and brain [Ca]s ranged from only 85% to 110% of respective CONT values. Choroid plexus [Ca] was increased by 37% after HID diet, but was decreased only 10% after LOD. KCa values at CSF, parietal cortex, and pons-medulla were negatively correlated with plasma ionized [Ca], whereas KCl values at CSF and brain were not different between the diet groups. The findings demonstrate that central nervous system [Ca] is maintained during chronic hypo- or hypercalcemia by saturable transport of Ca at brain barrier membranes. This transport does not seem to involve modulation by 1,25-dihydroxyvitamin D3.     

大鼠中枢神经系统衰老的形态学研究Ⅳ.大脑皮质锥体细胞树突棘的数量变化

用6、12与31个月的雄性Wistar大鼠的大脑Krieg 2、3区皮质,对其V层大锥体细胞的五段50μm长度内的树突棘做形态学定量研究。在Golgi法的切片中共计数了三个年龄组的151个细胞的725段树突的棘密度。结果表明,老年大鼠比成年和青年大鼠的棘密度普遍下降。其中以基树突与侧树突棘度下降最显著(减少24％左右),顶树突只中段有明显减少。老年大鼠锥体细胞还常出现胞体、树突及其分支的明显形态改变。     

Immunochemical Characterization of Pyruvate Dehydrogenase Complex in Rat Brain

Pyruvate dehydrogenase complex (PDHC) in rat brain was studied immunochemically, using antibodies against the bovine kidney PDHC, by immunoblotting, immunoprecipitation, inhibition of enzyme activity, and enzyme-linked immunoabsorbent assay (ELISA). The immunoblots showed that the antibodies bound strongly to the alpha peptide of the pyruvate dehydrogenase (E1) component, and to the dihydrolipoyl transacetylase (E2) and the dihydrolipoyl dehydrogenase (E3) components of PDHC. A similar immunoblotting pattern was observed in all eight brain regions examined. On immunoblotting of the subcellular fractions, these PDHC peptides were observed in mitochondria and synaptosomes but not in the postmitochondrial supernatants. This agrees with other evidence that brain PDHC is localized in the mitochondria. These results, together with those from sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the immunoprecipitin, also showed that the alpha E1, beta E1, and E3 peptides of rat brain PDHC are very similar in sizes to those of the bovine kidney PDHC, being 42, 36, and 58 kD, respectively. The size of the E2 peptide, 66 kD, is different from that of bovine kidney E2, 73 kD. The relative abundance of PDHC protein in nonsynaptic mitochondria was compared by enzyme activity titration and ELISA. Both methods demonstrated that the amount of PDHC antigen in the mitochondria from cerebral cortex is greater than that in the olfactory bulb mitochondria. This is consistent with the results of the activity measurement. The ELISA also showed that the PDHCs in both mitochondrial populations are antigenically similar.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cerebral Blood Flow and Oxidative Metabolism in Conscious Fischer-344 Rats of Different Ages

Abstract: The cerebral metabolic rates for O₂ and for glucose were measured in conscious, fasted male Fischer-344 rats at the ages of 3, 12, and 24 months, and cerebral blood flow was determined with ¹⁴C-iodoantipyrine. The metabolic rates for oxygen and glucose were obtained by multiplying blood flow by the O₂ and glucose concentration differences, respectively, between blood in the femoral artery and in the superior sagittal sinus. Mean cerebral blood flow and the metabolic rates for oxygen and glucose did not differ significantly (p > 0.05) between 3 and 12 or between 12 and 24 months. Nor did the arteriovenous differences for O₂ and for glucose change significantly with age. Because the superior sagittal sinus drains blood mainly from the cerebral cortex, the results indicate that average cerebral cortical oxidative metabolism, and the coupling ratios between the cerebral metabolic rate for oxygen and cerebral blood flow and between the cerebral metabolic rate for glucose and cerebral blood flow, do not change significantly with age in the Fischer-344 rat.     

Changes in the Expression of the αα Form of Enolase During Neuroblastoma Differentiation

Abstract: The relative amounts of the different enolase isozymes present in neuroblastoma cells change during differentiation. When differentiation is induced by low serum in the presence of DMSO (dimethyl sulfoxide), there is a 50% decrease in the concentration of enolase activity associated with the form αα, and an increase in the activity associated with the γ-containing isozymes (αγ plus γγ); in the absence of DMSO, there is no decrease in αα or in total enolase activity. In order to study the mechanism of the changes in αα, cells differentiated with low serum with and without DMSO were compared. Measurements of the concentration of the α antigen by microcomplement fixation and by immunotitration demonstrate that the decreased enolase activity in DMSO cells is due to a decreased concentration of the α antigen. Measurements of the relative rate of synthesis of the antigen show that the decreased concentration of the α antigen is due to a decreased rate of synthesis. Enolase in differentiated cells is sufficiently stable (t_1/2 > 100 h) that a comparison of the relative rates of degradation has not been possible. The decreased synthesis of the α subunit of enolase that occurs under these conditions appears to be a useful model system for studying the de-expression of the α gene that occurs in vivo during neuronal differentiation.     

Differential effects of protein malnutrition and ascorbic acid deficiency on histidine metabolism in the brains of infant nonhuman primates

Abstract: Male infant nonhuman primates (M. nemes-trina) born in captivity were used in the study. They were divided into three groups. The first group of three animals was fed a 20% casein diet and the second group of six monkeys received a 2.0% casein diet. The third group of four monkeys received a 20% casein diet totally devoid of ascorbic acid for 3.5 weeks before the diet was supplemented with ascorbic acid (20 mg/kg diet). All the diets were given to the animals in two daily rations of 100 g/animal. The monkeys fed a 2% casein diet failed to grow, and after about 3.5 months showed variable degrees of edema, hypoalbuminemia, evidence of psychomotor disturbance, depressed plasma levels of many essential amino acids, and other features consistent with the diagnosis of protein-energy malnutrition. Examination of the brains revealed significant alterations in the levels of histidine (+ 172%) and homocarnosine (+ 146%) in comparison with the control well-fed monkeys. Associated with the increase in brain histidine was a marked elevation of brain histamine level. Protein deficiency also led to poor brain retention of ascorbic acid but not to the same degree observed in the ascorbic acid-deficient animals. The latter group of animals, after receiving their diet for about 8 months, demonstrated a modest elevation in the plasma levels of most amino acids in comparison with controls. Ascorbic acid deficiency elicited a significant reduction (p < 0.01) in brain level of histidine, with hardly any change in homocarnosine level. In addition, vitamin C deficiency produced elevation of brain histamine level comparable to findings in the protein-energy-deficient monkeys. The results suggested that protein deficiency raised brain histamine level mainly through increased availability of the precursor amino acid histidine, while defective degradation might account for the increased brain level of this amine in ascorbic acid-deficient monkeys. Histamine has been proposed to have a predominantly depressant action on relevant neurons, and has also been shown to participate with other neuro-transmitters in influencing the function of the pituitary gland by regulating release of the hypothalamic hormones into the portal vessels. The relevance of the findings of marked increases in brain histamine in experimental protein and ascorbic acid deficiencies to the behavioral and extensive endocrinological alterations seen in human malnutrition deserves some intensive investigation.     

In Vivo Release from Cerebral Cortex of [14C]Glutamate Synthesized from [U-14C]Glutamine

Awake, unrestrained, and behaviourally normal animals with superfusion cannulae implanted over the sensorimotor cortex were used in a study of the capacity of infused [U-14C]glutamine for labelling glutamate and other amino acids released by depolarising stimuli. A spontaneous background release of [14C]glutamate was detected. This was increased by tityustoxin (1 microM). The specific radioactivity of glutamate increased eightfold during the evoked-release period. [14C]Aspartate was also detected and showed increased release, but not increased specific labelling, in response to depolarisation. Evoked gamma-aminobutyric acid (GABA) release occurred but only small amounts of [14C]GABA were detected. Glutamine showed increased rates of uptake to the sensorimotor cortex during stimulation periods, suggesting an accelerated breakdown via glutaminase.     

Evolution cyclique des glandes cérébrales au cours de l'intermue chez Lithobius forficatus L. (Myriapode Chilopode)

Résumé Chez le Chilopode Lithobius forficatus L., les cellules parenchymateuses des glandes cérébrales présentent, durant l'intermue, un cycle sécrétoire caractérisé essentiellement par l'évolution de l'activité golgienne. Pendant les périodes de sécrétion, les ribosomes, groupés en polysomes, et les éléments ergastoplasmiques sont très abondants; pendant les périodes de repos, les ribosomes sont isolés et l'ergastoplasme est vésiculeux. Les autres organites cellulaires montrent peu de variations.Le cycle sécrétoire ne se superpose pas exactement au cycle d'intermue; il commence lors de la prémue. Peu de temps après l'exuviation, il est possible d'observer des figures qui semblent liées au rejet du produit de sécrétion. L'étude ultrastructurale des glandes cérébrales en fonction de l'intermue confirme l'existence de l'activité cyclique mise en évidence par les résultats expérimentaux.

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Ultrastructural signs of cyclic secretory activity in the cerebral glands of Lithobius forficatus during intermolt

Summary During the molting cycle of Lithobius forficatus L. (Chilopoda), the parenchymal cells of the cerebral glands exhibit signs of cyclic secretory activity consisting essentially of changes in the appearance of the Golgi complex. During active periods of secretion, polysomes and ergastoplasmic elements are very numerous; free ribosomes and vesiculated ergastoplasmic cisternae characterize the periods of inactivity. Other cytoplasmic organelles undergo few variations. The secretory cycle as determined by cytological criteria does not exactly match the molting cycle. The first ultrastructural signs of activity appear during premolt. Shortly after ecdysis, images suggesting the release of secretory material can be observed. The electron microscopic data on cyclic changes during intermolt substantiate the existence of activity cycles in the cerebral glands as determined by physiological experiments.

     

Quantitative studies of postnatal changes in synapses in rat superficial motor cerebral cortex

Summary Quantitation of synapses at different postnatal ages has been undertaken in the cerebral cortex of the rat. In this study axial ratios of presynaptic bags, proportion of cortex occupied by presynaptic bags and numbers of synapses per unit volume of cortex have been estimated. Observations on synaptic vesicle packing densities have also been made.Synaptic bags become increasingly spherical up to 7 days of age and become more elongated thereafter. The proportion of cortex occupied by presynaptic bags increases rapidly up to 7 days of age and then at a decelerated rate up to maturity. The number of synapses per unit volume increases slowly over the first four days after which there is a rapid increase to 14 days, followed by a decelerated rate.The average presynaptic bag shows marked changes in volume with increasing age which indicate the probability of two stages of synaptic development. This two stage development is further reflected in the estimates on vesicle packing densities. The implications of the results are discussed in relationship to changes in functional activity of the cortex during postnatal development.The authors wish to express their thanks to Mr. R. Birchenough and Mr. J. Manston for much technical assistance.     

Role of the Blood-Brain Barrier in the Formation of Long-Chain ω-3 and ω-6 Fatty Acids from Essential Fatty Acid Precursors

Elongated, more highly polyunsaturated derivatives of linoleic acid (18:2 omega-6) and linolenic acid (18:3 omega-3) accumulate in brain, but their sites of synthesis and mechanism of entry are not well characterized. To investigate the role of the blood-brain barrier in this process, cultured murine cerebromicrovascular endothelia were incubated with [1-14C]18:2 omega-6 or [1-14C]18:3 omega-3 and their elongation/desaturation products determined. The major metabolite of 18:2 omega-6 was 20:4 omega-6, whereas the primary product from 18:3 omega-3 was 20:5 omega-3. Although these products were found primarily in cell lipids, they were also released from the cells and gradually accumulated in the extracellular fluid. Eicosanoid production was observed from the 20:4 omega-6 and 20:5 omega-3 that were formed. No 22:5 omega-6 or 22:6 omega-3 fatty acids were detected, suggesting that these endothelial cells are not the site of the final desaturation step. Although the uptake of 18:3 omega-3 and 18:2 omega-6 was nearly identical, 18:3 omega-3 was more extensively elongated and desaturated. Competition experiments demonstrated a preference for 18:3 omega-3 by the elongation/desaturation pathway. These findings suggest that the blood-brain barrier can play an important role in the elongation and desaturation of omega-3 and omega-6 essential fatty acids during their transfer from the circulation into the brain.