Phylogenetic and regional variations in brain gangliosides of tetrapods.

1. Ganglioside patterns were analyzed from four neural tissues (medulla, midbrain, forebrain and retina) in a representative from each of the four tetrapod classes. 2. Regional variations in ganglioside patterns were noted within some species, but differences were greater across phylogenetic lines. 3. These results suggest that evolutionary history plays a greater role than neural differentiation in the expression of brain ganglioside patterns.     

Apomorphine: sterotyped behavior and regional distribution in rat brain.

The distribution of apomorphine following subcutaneous injection of 20 mg/kg (as the hydrochloride) was measured spectrofluorometrically in specific regions of rat brain. Measurable concentrations were found in the brain within a few minutes of injection, the drug was still detectable for at least 60 min in all regions, and maximum concentration was observed 20 min after injection. Stereotyped behavior, characteristic of apomorphine action, followed a time course parallel to accumulation of the drug in the brain.     

The regional metabolism of 5-hydroxytryptamine in mouse brain in vitro.

The relative rates of formation of 5-hydroxytryptophol (5-HTOL) and 5-hydroxyindoleacetic acid (5-HIAA) from exogenous 5-hydroxytryptamine, showed regional variations when examined in homogenates of seven separate areas of mouse brain. 5-HTOL production was highest in the cerebellum, and lowest in the corpus striatum, whereas the production of 5-HIAA was greatest in the hypothalamus. Addition of NADPH was shown to increase the formation of the alcohol catabolite in whole brain homogenates. The production of 5-HTOL decreased in the brain homogenates of mice which had previously been injected with phenytoin sodium or oxypertine, with the latter also causing a fall in overall 5-HT metabolism.     

Beta-endorphin: regional levels profile in the brain of the human infant.

Immunoradiometrical determinations of beta-endorphin (beta-EP) levels in 29 discrete brain regions from a series of victims of "Sudden Infant Death Syndrome" yielded a uniformly low levels profile in various areas of telencephalon, thalamus, pons, cerebellum and medulla oblongata. This low levels profile was interrupted by intermediate and high beta-EP levels in the midbrain and in two diencephalic zones. This study provides, for the first time, a comprehensive, neurochemically determined regional profile of beta-EP levels in the brain of the human infant.     

Alterations in regional brain neurotensin concentrations produced by atypical antipsychotic drugs.

Classical antipsychotic drugs, such as haloperidol, have been shown to increase the concentrations of neurotensin (NT) selectively in the nucleus accumbens and caudate nucleus of the rat. Several novel, putative antipsychotic drugs have also been found to produce increases in NT content in one or both of these brain regions. The present study sought to compare the effects of chronic treatment with three clinically efficacious atypical antipsychotic drugs, sulpiride, rimcazole and remoxipride, on regional brain NT concentrations to those of haloperidol. The concentrations of NT in five discrete brain regions were determined by a sensitive and specific radioimmunoassay. As previously reported, haloperidol increased NT concentrations in both the nucleus accumbens and caudate nucleus. Sulpiride and rimcazole produced significant increases in the concentration of NT in the caudate. NT concentrations were unaltered in any brain region by remoxipride at either of the doses tested. These data provide additional evidence for specific increases in regional brain NT concentrations produced by antipsychotic drugs.     

Effects of neonatal pantothenic acid deficiency on brain lipid composition in rats.

—Studies were made of the effects of pantothenic acid deficiency during the neonatal period on brain lipids in rats. Mothers with 6–8 pups to a litter were fed from soon after birth a diet either normal or deficient in pantothenate. An additional control group (restricted controls) was pair-fed with the deficient group. Significant deficits were found in the pups of the pantothenate-deficient group and in those of the restricted controls with regard to body weight, brain weight and brain concentration of lipids (total lipid, cholesterol, phospholipid, galactolipid and gangliosides) at 21 days of age. The deficits in both these groups were comparable. The results suggest that the effects of pantothenate deficiency may be due to the resulting growth deficit rather than to the deficiency of pantothenate per se.     

Levels of cyclic nucleotides in mouse regional brain following 300 ms microwave inactivation.

Abstract— The uniformity and speed of inactivation of mouse brain adenylate cyclase, guanylate cyclase and cyclic nucleotide phosphodiesterase were measured after 6 kW microwave irradiation (MWR). Inactivation of enzymes was uniform throughout the brain during heating and 100% loss of activity was evident after 300 ms. MWR. For comparison of effects of inactivation times on levels of cyclic nucleotides measured in regional brain areas, cyclic AMP and cyclic GMP were estimated after 1.5 kW MWR requiring 4 s of heating and 6 kW MWR requiring 300 ms. Except for corpus striatum, uniformly lower levels of cyclic AMP were measured following 300 ms vs. 4s MWR . There was no change in cyclic GMP levels in regional brain areas after 4s vs. 300 ms MWR . Cyclic AMP and cyclic GMP were measured from the same regional brain tissue samples after 300 ms and ratios calculated. The finding of much lower cyclic AMP:cyclic GMP ratios than had previously been reported suggests that slow inactivation times provide for the measurement of regional brain cyclic nucleotide values which are not consistent with the in-vivo state.     

Subclinical zinc deficiency impairs human brain function

Experiments in other species showed zinc essential for brain growth and function. Six randomized controlled comparative treatment experiments in Chinese and Mexican-American low-income children, aged 6-9 years, middle-income US adolescents, middle-income US premenopausal women and middle income US men, found that subclinical zinc deficiency changes brain function. Simultaneous treatment with a broad mixture of other micronutrients and/or an adequate omnivorous diet appeared to enhance the efficacy of zinc.     

N-syndecan deficiency impairs neural migration in brain

N-syndecan (syndecan-3) is a transmembrane proteoglycan that is abundantly expressed in the major axonal pathways and in the migratory routes of the developing brain. When ligated by heparin-binding (HB) growth-associated molecule (GAM; pleiotrophin), N-syndecan mediates cortactin-Src kinase-dependent neurite outgrowth. However, the functional role of N-syndecan in brain development remains unexplored. In this study, we show that N-syndecan deficiency perturbs the laminar structure of the cerebral cortex as a result of impaired radial migration. In addition, neural migration in the rostral migratory stream is impaired in the N-syndecan-null mice. We suggest that the migration defect depends on impaired HB-GAM-induced Src kinase activation and haptotactic migration. Furthermore, we show that N-syndecan interacts with EGF receptor (EGFR) at the plasma membrane and is required in EGFR-induced neuronal migration.     

Copper deficiency in the developing rat brain: evidence for abnormal mitochondria.

Abstract— Copper deficiency was produced in developing rats by feeding a low copper diet to rats during gestation and lactation and providing the offspring the same diet. The progeny developed similar to those of an earlier model based on preconception depletion followed by marginal supplementation during gestation. Copper levels were greatly reduced in the brain, iron levels were slightly depressed, and no differences in zinc content were found. Electron microscopic examination of brain tissue revealed the presence of enlarge mitochondria from copper-deficient animals. Isolated mitochondria from copper-deficient rats showed a 30% reduction in the rate of both succinate and glutamate oxidation, and for glutamate, the respiratory control ratio (RCR) was decreased by 60%. Difference spectra displayed a four-fold reduction in cytochrome a+a₃ and slight increases in cytochrome b, c₁ and c. Enzyme analysis of isolated mitochondria revealed a five-fold decrease in cytochrome oxidase, slight increases in succinic dehydrogenase and fumarase, and small decreases in hexokinase and monoamine oxidase. No difference in peroxidation of brain lipids was evident. Determination of metabolites from fast frozen tissue suggested that the copper-deficient brain was in a more reduced state based on a doubling of both the lactate/pyruvate and α-glycerol-P/dihydroxyacetone-P ratios. Creatine-P, ATP, and ADP levels were not different.     

Caffeine and regional brain monoamine utilization in mice

Caffeine (100 and 200 mg/kg, 30 min., i.p.) selectively altered the regional utilization of monoamines in the brains of mice. This depended upon the specific neurotransmitter and metabolite studied. Caffeine increased serotonin (5HT) utilization a dramatic ten-fold in the OB but decreased 5HT utilization in the HT. No 5HT changes were seen in other brain regions. Caffeine markedly increased norepinephrine (NE) utilization in the olfactory bulbs (OB), olfactory tubercles (OT), prefrontal cortex (PC), amygdala (AMY), hypothalamus (HT) and hippocampus (HC). Caffeine increased dopamine (DA) utilization in the OB, OT, PC, septum (SP), HT and thalamus (TH) but by various metabolic routes. The selective regional alterations in monoamine utilization produced by caffeine may be relevant to caffeine's central stimulatory effects. Limbic structures are predominantly involved. These changes may have important clinical and research implications. For example, the profound effect of caffeine on OB monoamines indicates that it may serve as a meaningful tool in olfactory research, including the bulbectomy model. Caffeine may also be useful in other limbic system behavioral models.