Compartmentation and exchangeability of brain amino acids: evidence from studies of transport into tissue slices

Rates of exchange of free amino acids between plasma and brain in mice

The rate of appearance of label in the brain in mice following the intraperitoneal or intravenous injection of tracer doses of amino acids was measured in short time periods (1-8 min). Amino acid flux varied between 2 and 10 nmol/min per g brain for the amino acids used. Defining half-life as the uptake of labeled amino acid amounting to 50% of endogenous levels, a short half-life (between 3 and 30 min) was found for the essential amino acids. The half-life of the nonessential amino acids varied between 2 and 24 h, depending on their level in brain. Flux (exchange) of an amino acid was increased when the level of amino acids belonging to the same transport class was increased by intracerebral injection. Protein-free diet resulted in decrease in some amino acids, increase in others; flux was altered parallel to changes in brain levels in animals on this diet. The stercospecificity of exchange and the substrate specificity of effects of altered brain amino acids indicate that exchange occurs via mediated transport. Mediated exchange was present in immature brain. Heteroexchange (flow of one amino acid causing the counterflow of a related amino acid) may play an important part in cerebral homeostasis.

Glucose and amino acid metabolism in chick telencephalon slices: changes with incubation conditions and animals' development

Glucose and amino acid metabolism in 1- and 30-day-old chick telencephalon slices was studied in two incubation media in the presence or in the absence of a continuous oxygenation. Medium 1 has a composition and a tonicity similar to cerebrospinal fluid, medium 2 is hypertonic and does not contain any K+ ions. The incorporation of glucose carbon into amino acids and the distribution of radioactivity between the different amino acids are close to the ones observed in the chick brain in vivo only when the slices are incubated in medium 1, with oxygen at 30 days and without oxygen for the 1-day-old chick. It also appears that if oxygenation is necessary for incubation of mature brain tissue in vitro, the absence of the medium oxygenation is more suitable for the study of glucose metabolism in 1-day-old chick brain slices.

Changes in medium radioactivity and composition accompany high-affinity uptake of glutamate and aspartate by mouse brain slices

In measurements of high affinity transport in tissue slices, the incubation medium is often treated as an "infinitely large pool". External substrate concentrations, even at the micromolar level, are assumed to be constant and metabolic interactions between tissue and medium are neglected. In the present report we describe experiments in which glutamic and aspartic acid uptake by mouse brain slices were studied using techniques that could test these assumptions. Cerebral hemispheres were cut into 0.1 mm sections and about 90 mg of tissue incubated in 10 ml of oxygenated medium. After 45 minutes of equilibration, radioactive substrates were added and the concentrations and specific activities of the amino acids and their metabolites in the medium were determined. During the first 10 min following substrate addition, rapid decreases in glutamic and aspartic acid concentrations in the medium were accompanied by large decreases in specific activity caused by the continuous release of these amino acids from the tissue. In addition, extensive conversion of both substrates to glutamine and the preferential accumulation of this metabolite, in the medium, was found. These results demonstrate that metabolism and release occur simultaneously with uptake during transport experiments in vitro and that these processes can take place in specific tissue compartments. It is therefore necessary to measure the tissue and medium concentration levels of amino acids along with their radioactivity in such experiments, since all three processes (transport, metabolism, and compartmentation) are interrelated in the clearance of amino acids from the incubation medium and probably from the extracellular spaces in vivo as well.

Erythrocyte glycine in depressed, hypomanic, and euthymic bipolar patients treated with lithium carbonate

Red blood cell (RBC) glycine levels were examined in 27 bipolar patients, treated with lithium carbonate for a minimum of 8 months, who were either hypomanic, depressed, or euthymic in their mood. We found no difference in the RBC glycine or in the RBC: plasma glycine ratio between the hypomanic, depressed, or euthymic patients (P less than 0.1). There were statistically significant differences in RBC glycine levels in lithium-treated euthymic patients and normal controls. There was a strong positive correlation between serum lithium levels and both RBC glycine levels and the RBC: plasma glycine ratio.

Aromatic amino acid incorporation into proteins in rat brain slices: influences of other amino acids affecting transport

Incorporation of [3H]tryptophan, [3H]tyrosine and [3H]phenylalanine into proteins has been studied in cerebral coronal slices from adult and 1-day-old rats. Unlabelled amino acids greatly increased (histidine) or decreased (leucine, phenylalanine, tyrosine, tryptophan) intracellular levels of the [3H]amino acids, but only slightly decreased their incorporation rates. Effects on uptake were similar in experiments with adult and newborn rats, but patterns of protein synthesis inhibition seemed to differ. Amino acid uptake and subsequent incorporation into proteins were thus not closely associated. Incorporation in slices from adult rats was much slower than in those from newborn rats, and moreover, one half of it was cycloheximide-insensitive. The difference inhibition patterns by other amino acids may thus be explained by multiple mechanisms in cerebral amino acid incorporation into proteins.

Distributive profiles of free and protein-incorporated tryptophan and valine in cerebral cortex slices from adult and 2-day-old rats

The distribution of the specific radioactivity and the incorporation into protein of [3H]tryptophan and [3H]valine at varying layers from surface to centre were measured in incubated slices of cerebral cortices from infant and adult rats. Specific radioactivity in free amino acids was in both age groups highest in the intact surface layer. Incorporation of tryptophan into protein was even in slices from adult rats but much less than the average in the surface layers in slices from infant rats. Incorporation of valine exhibited similar heterogeneity in both age groups. The results suggest in brain slice preparations a zonal compartmentation of amino acid and protein metabolism which varies for different amino acids.

Brain slice protein degradation and development

Protein degradation rates were measured in brain slices prepared from rats of various ages. This was done by adding the protein synthesis rate, determined by incorporation of a labeled precursor, and the net protein degradation rate, determined by measuring the changes with time of total free amino acids. These rates are about 30% higher than those previously calculated from data on protein synthesis rates and protein accumulation rates in vivo. The protein degradation rates in brain slices diminish with age; i.e., 2-day cerebellum greater than 2-day cerebral hemisphere greater than 12-day cerebral hemisphere greater than young adult cerebral hemisphere. Protein degradation rates in slices from young brain are initially slightly higher than protein synthesis rates, resulting in a small net degradation with time. Unlike slices from adult brain, the protein degradation rates in slices from young brain decline only modestly with time for as much as 100 min of incubation. The characteristics of protein degradation in brain slices from young animals are roughly similar to some of the data calculated for protein degradation in vivo, suggesting that this system may prove useful for studying factors which control or affect brain protein degradation.

Rat brain protein synthesis declines during postdevelopmental aging

Using improved methods to measure brain protein synthesis in vivo (Dunlop et al., 1975) we have established that brain protein synthesis significantly declines in forebrain, cerebellum and brain stem when mature rats (3 months old) are compared to old rats (22.5 months old). The incorporation of (3H) L-lysine into forebrain protein is reduced 11% in 10.5 month old rats compared to 3 month old rats. A further reduction of 9% occurred between 16.5 months and 22.5 months. Our data suggest that reduced levels of protein synthesis initiation may be responsible, at least in part, for this age-related decline.

Utilization of acetate by chick brain during postnatal maturation

1. The study of the compartmentation of glutamate metabolism has been performed in the chick brain in vivo and in vitro in the presence of [U-14C]acetate between day 1 and day 30 of postnatal maturation. 2. The compartmentation of glutamate metabolism in vivo appears between day 1 and day 4 after hatching in the cerebral hemispheres and optic lobes. It is however more precocious in the optic lobes. In the cerebellum, it appears later, at about day 4 after hatching. The compartmentation of glutamate metabolism appears at the same time as the rapid incorporation of glucose into amino acids takes place in the cerebral hemispheres and the optic lobes. 3. In the chick telencephalon in vitro, the compartmentation of glutamate metabolism is visible from day 1 after hatching onwards. This difference is undoubtedly linked to the absence of an interference of glucose metabolism with acetate metabolism in vitro, and to the presence of a third compartment in the cerebral slices.

Tissue concentrations of free amino acids in term human placentas

Five human term placentas were analyzed for total free amino acid concentrations. Calculation of tissue fluid distribution via 14C-inulin space enabled an estimation of placental intracellular amino acid concentrations based upon cord and maternal plasma concentrations. Maximum and minimum estimates for amino acid concentration in intracellular water are given. Data are compared to concentrations in organs of various species. Taurine was present in the highest concentration (3.529 +/- 1.120 mumoles per gram wet weight). Glutamic and aspartic acids, alanine, glycine, and glutamine were all present in concentrations greater than 0.5 mumoles per gram wet weight.

Energetics of amino acid transport into brain slices: effects of glucose depletion and substitution of Krebs' cycle intermediates

Amino acid uptake by slices of brain is greatly diminished by incubation of the slices in glucose-free media. Uptake can be restored by the addition of a number of substrates, e.g., lactate, citrate, or oxaloacetate. The mixture of succinate, malate, and pyruvate (SMP, 20, 5, and mM) restored amino acid uptake better than glucose after brain slices were incubated in glucose-free media to deplete endogenous energy stores. The degree of restoration of uptake was different with the various amino acid transport classes and was independent of the restoration of ATP levels in the tissue. After restoration of uptake with SMP the amino acid uptake was resistant to NaF, but was markedly more sensitive to arsenite and oligomycin. The results indicate the coupling of mitochondrial energy transducing systems to transport.