AMINO ACID TRANSPORT IN PERIPHERAL NERVE: SPECIFICITY OF UPTAKE

Amino acid uptake has been studied in desheathed frog sciatic nerve. Results indicate that at least two types of processes are involved: a non-saturable process, possibly simple diffusion, and a saturable, carrier-mediated process. There appear to be several carrier-mediated transport mechanisms, which can be separated on the basis of their substrate specificity as follows: small neutral, large neutral, β-alanine, acidic, basic, aromatic and heterocyclic, and proline. The specificity of some of the mechanisms is incomplete and these can transport certain amino acids from other groups to a limited extent. The percentage of total uptake by a saturable process is highly variable. Basic, acidic, and those amino acids containing aromatic or heterocyclic ring structures are taken up primarily by a saturable process; small and large neutral amino acids and proline are taken up primarily by a non-saturable process.     

AMINO ACID AND UREA UPTAKE IN TEN SPECIES OF CHLOROPHYTA1

The Uptake of radioartively-labelled mixed amino acids, arginine, lysine, leucine, glutamic acid and urea was examined in six species of Volvocales and four species of Chlarococcales grown in nitrate-containing medium. Nonradioactive amino acids in excess were used to estimate specificity of amino and carriers in selected cases. All ten species possess salurable (hence, carrier-mediated) systems for uptake of both arginine and urea. In all Volvacales and one Chlorococcales, the arginine-speciftc carrier (which also transported lysine with lower efficiency) was the only amino acid carrier detected. Three species of Chlororoccales appear to possess a separate carrier for lysine and two of these appear to possess at least one additional carrier that is involved in uptake of non-basic amino acids.     

脑性瘫痪与血浆游离氨基酸

<正> 脑性瘫痪(Cerebral Hemiplegie)是一组虽发生于婴幼儿时期的先天性疾病,但也涉及后天因素。表现为出生后,出现双侧性肌张力及功能不全,导致非进行性脑性运动障碍及智力发育不全。病理特征是锥体系受损,甚至累及锥体外系、小脑、脑干以及脊髓等,按临床症状分为痉挛型、运动障碍型、共济失调型以及混合型等。     

PROPERTIES OF THE UPTAKE AND RELEASE OF GLUTAMIC ACID BY SYNAPTOSOMES FROM RAT CEREBRAL CORTEX

Abstract– (1) The uptake and release of glutamic acid by guinea-pig cerebral cortex slices and rat synaptosomal fractions were studied, comparing the naturally occurring l - and non-natural d -isomers. Negligible metabolism of d -glutamic acid was observed in the slices. (2) Whereas in the cerebral slices the accumulation of glutamic acid was almost the same for the two isomers, d -glutamic acid was accumulated into the synaptosomal fraction at a markedly lower rate than was the L-isomer. (3) The uptake systems for d -isomer into the slices and synaptosomal fraction were found to be of single component, in contrast with the two component systems, high and low affinity components, for the uptake of l -glutamic acid. The apparent K_m values for the uptake of d -glutamic acid into the slices and synaptosomal fraction were comparable with those reported for the low affinity components for l -isomer. The uptake systems for d -glutamic acid were dependent on the presence of Na⁺ ions in the medium, like those for l -glutamic acid and GABA. (4) The evoked release of radioactive preloaded d -glutamic acid was observed both from the slices and synaptosomal fraction following stimulation by high K⁺ ions in the medium. From these observations, it is evident that the evoked release of an amino acid by depolarization in vitro is not necessarily accompanied by a high affinity uptake process. (5) The uptake of l -glutamic acid, expecially into the synaptosomal fraction, was highly resistant to ouabain. On the other hand, the uptake rate of d -glutamic acid and GABA into the synaptosomal fraction was inhibited by varying concentrations of ouabain in accordance with the inhibition for brain Na-K ATPase. (6) The uptake of l -glutamic acid into subfractions of the P₂ fraction was studied in relation to the distribution of the ‘synaptosomal marker enzymes’. An attempt to correlate the activities of enzymes of glutamic acid metabolism with the uptake of l -glutamic acid into the synaptosomal fraction from various parts of brain was unsuccessful. The high affinity uptake of l -glutamic acid was found to be very active in the synaptosomal fraction from any part of brain examined.     

THE EFFECT OF DELTA-AMINOLAEVULINIC ACID ON THE UPTAKE AND EFFLUX OF AMINO ACID NEUROTRANSMITTERS IN RAT BRAIN SYNAPTOSOMES

Abstract— δ-Aminolaevulinic acid (δ-ALA) is an omega amino acid structurally similar to γ-aminobutyric acid (GABA) and l -glutamate. We have examined the effect of δ-ALA on the uptake and efflux of radiolabelled GABA and l -glutamate in rat cortical synaptosomes and report: (1) low concentrations of δ-ALA reduced the potassium-stimulated release of [³H]GABA from the synaptosome preparation. This effect was reversed by the GABA receptor antagonist bicuculline. We postulate that GABA release is modulated by a feedback mechanism on presynaptic GABA receptors, and that δ-ALA has agonist activity at these receptors. (2) δ-ALA at high concentrations (0.75-5.0 m m ) stimulated the efflux of l -[¹⁴C]glutamate from preloaded synaptosomes. (3) δ-ALA had no effect on potassium-stimulated release of l -glutamate. (4) Uptake of labelled l -glutamate was inhibited by δ-ALA in a noncompetitive fashion. (5) Synaptosomes did not accumulate [¹⁴C]δ-ALA in the range 0.5-50 δ m . These results are discussed in relation to the control of GABA release from nerve endings, and the role of δ-ALA in the neuropsychiatric manifestations of the acute porphyric attack.     

AMINO ACID TRANSPORT IN PERIPHERAL NERVE: ENERGY AND SODIUM DEPENDENCE

Abstract— The energy and sodium dependence of the several carrier-mediated mechanisms for amino acid uptake have been studied in frog sciatic nerve. The different transport mechanisms are found to be variable in their dependence on sodium and metabolic energy. Saturable uptakes of lysine, phenylalanine and valine are relatively independent of the presence or absence of sodium in the incubation medium, indicating that uptakes by those mechanisms subserving basic, large neutral amino acids, and those amino acids containing aromatic or heterocyclic ring structures are largely sodium independent. Saturable uptakes of glutamic acid, proline, glycine and β-alanine are considerably reduced in the absence of sodium; thus carrier mechanisms for uptake of acidic, small neutral amino acids, β-alanine and proline are highly sodium dependent. The efficacies of several cations in substituting for sodium is variable; greatest inhibitions are found when potassium is used to replace sodium.
With the exception of proline, those mechanisms found to be sodium dependent are also found to be energy dependent, since they are inhibited by both DNP and lowered temperature. Although proline uptake is sodium dependent, proline uptake is stimulated by DNP and relatively insensitive to lowered temperature.     

CARBOHYDRATE AND AMINO ACID METABOLISM IN RAT CEREBRAL CORTEX IN MODERATE AND EXTREME HYPERCAPNIA

—The time course of changes in glycolytic and citric acid cycle intermediates and in amino acids was studied in acute and steady state hypercapnia. Experiments on unanaesthetized animals exposed to 10% CO₂ for 10, 20 and 60s showed that there was a transient decrease in glycogen concentration, progressive increases in glucose-6-phosphate and fructose-6-phosphate and decreases in pyruvate and lactate. During this time the levels of amino acids and Krebs cycle intermediates did not change, except for a small fall in malate at 60s. The results indicate that there was a decrease in glycolytic flux due to an inhibition of the phosphofructokinase reaction. Since the tissue levels of phosphocreatine, ATP, ADP and AMP were unchanged inhibition of phosphofructokinase was probably due to the fall in pH. Anaesthetized animals were exposed to about 5% CO₂ (for 2, 5, 15, 30 and 60 min) or to about 45% CO₂ (for 5 and 15 min). Except for succinate, which increased, all citric acid cycle metabolites analysed (citrate, α-ketoglutarate, fumarate and malate) decreased with the rise in CO₂-tension. The sum of the amino acids analysed (glutamate, glutamine, aspartate, asparagine, alanine and GABA) decreased at extreme hypercapnia. The results suggest that Krebs cycle intermediates and amino acids are partly used as substrates for energy production when there is reduced pyruvate availability due to hypercapnia. It is proposed that amino acid carbon is made available for oxidation via transamination (aspartate aminotransferase reaction) and deamination (glutamate dehydrogenase reaction) and that citric acid cycle intermediates are metabolized following a reversal of reactions usually leading to CO₂ fixation.     

氨基酸的表面特性和溶剂化自由能

我们计算了氨基酸的溶剂可接近面积,局域偶极矩及表面电场.结果显示了亲、疏水基团与水相互作用具有不同的微观本质,由此提出了新的估计氨基酸溶剂化能的方法.     

SPECIFICITY AND KINETIC PROPERTIES OF MONOSACCHARIDE UPTAKE INTO GUINEA PIG CEREBRAL CORTEX IN VITRO

Abstract— The uptake into the non-raffinose space of cerebral cortex slices of a number of ¹⁴C-labelled glucose analogues has been studied. Evidence on competition with glucose for the transport process has been used to derive information on the substrate specificity of sugar uptake to the brain. The kinetic properties of the uptake of 2-deoxygIucose indicate that the transport is a facilitated process rather than diffusion. Classical competition between glucose and 2-deoxyglucose for transport is shown and arguments are advanced for regarding glucose as a competitive inhibitor of 2-deoxyglucose transport. The apparent K_m for deoxyglucose is 10 mM and for glucose is suggested to be of the order of 5 mm , The value of such a kinetic approach to sugar transport in various conditions is discussed.     

GLUCOSE AND AMINO ACID METABOLISM IN SOME INVERTEBRATE NERVOUS SYSTEMS

(1) The in vitro metabolism of [U-¹⁴C]glucose and [U-¹⁴C]glutamate was compared in snail, octopus and locust ganglia, and in rat cerebral cortex. (2) The metabolic patterns are quantitatively similar. The major labelled metabolites formed from glucose or glutamate by rat cortex and the invertebrate systems were CO₂, aspartate, glutamate, glutamine and alanine. γ-Aminobutyric acid (GABA) was formed in substantial amounts only by locust and rat. (3) A much larger proportion of labelled glucose and glutamate was converted to alanine by the invertebrates compared with rat cortex, although ¹⁴CO₂ production was lower. (4) The effect of glucose in reducing aspartate formation and stimulating glutamine formation from [U-¹⁴C]glutamate in mammalian cortex was observed in the locust but not in the molluscs. (5) Labelled citric acid cycle intermediates were formed in substantial quantities from glucose and glutamate only by snail and locust.     

METABOLIC PROPERTIES OF A PURIFIED PREPARATION OF LARGE FRAGMENTS OF THE CEREBELLAR GLOMERULI: GLUCOSE METABOLISM AND AMINO ACID UPTAKE

Glomerulus particle preparations contain large fragments of the cerebellar glomeruli and are composed almost exclusively of well-defined neuronal processes (Balázs et al., 1975). The metabolic competence of the glomerulus particles was demonstrated by their ability to convert [¹⁴C]glucose to ¹⁴CO₂ and lactate at a linear rate for over 1 h. The preparations also transported deoxyglucose via an high affinity uptake system (K_T= 0.2-0.5 mM). The kinetics of uptake of various labelled amino acids were also studied. Apparently high affinity uptake systems (K_T values about 10^-5 M) were found for thc putative transmitters GABA, glycine, glutamate, and aspartate, but not for leucine, serine, and tyrosine. The maximal velocity of high affinity uptake was the greatest for GABA (about 15 nmol/mg protein per 10 min), while glycine was taken up at about 50%, and aspartate and glutamate at only 13% of the rate obtained with GABA. High affinity uptake of glycine required Na⁺ (half maximal uptake at 70 mM-NaCl). Inhibition of glucose transport and glycolysis, electron transport, or oxidative phosphorylation also depressed high affinity uptake of glycine. 2,4-Diaminobutyric acid was a potent competitive inhibitor of GABA uptake (K₁ approx 22 μM), while β-alanine and glycine had a relatively minor inhibitory effect on the uptake of GABA.     

AMINO ACID TRANSPORT IN NITZSCHIA OVALIS ARNOTT1,2

The marine diatom Nitzschia ovalis possesses at, least 3 amino acid uptake systems, specific for transport of acidic, polybasic, and, neutral amino acids. Maximum uptake velocity (V_max) for each, site is inversely related to the nitrogen content of the cell, and to the nitrogen available in the culture medium. Transport, of polybasic amino acids occurs throughout the course of growth in batch, culture, but the V_max increases dramatically as the culture ages and nitrogen/cell reaches a low value. K_s does not, change significantly. Acidic and neutral amino acids are taken up only by cells harvested from nitrogen-poor culture. It appears that amino acid transport is repressed by high concentrations of nitrogen in the medium. Under natural conditions, where nitrogen concentrations are low, the contribution of amino acid uptake to the nitrogen economy of Nitzschia populations may be significant.     

PERIODIC CHANGES IN RATE OF AMINO ACID UPTAKE DURING YEAST CELL CYCLE

Uptake of amino acids is a complex process but in cells growing with ammonia as sole nitrogen source the initial uptake rate of amino acids is a measure of the transport capacity of the uptake system (permease). In synchronous cultures of Saccharomyces cerevisiae amino acids were transported at all stages of the cell cycle. However, for any one amino acid the initial uptake rate was constant for most of the cycle and doubled during a discrete part of the cycle. Thus, for a variety of amino acids the functioning amino acid transport capacity of the membrane doubles once per cycle at a characteristic stage of the cycle. Arginine, valine, and phenylalanine exhibit periodic doubling of uptake rate at different stages of the cell cycle indicating that the transport of these amino acids is mediated by three different systems. Serine, phenylalanine, and leucine exhibit periodic doubling of the uptake rate at the same stage of the cycle. However, it is unlikely that serine and phenylalanine share the same transport system since the uptake of one is not inhibited by the other amino acid. This phenomenon is analogous to the periodic synthesis of soluble enzymes observed in S. cerevisiae.     

POTASSIUM AND AMINO ACID TRANSPORT IN HUMAN LEUKOCYTES EXPOSED TO PHAGOCYTIC STIMULI

Influxes of potassium and amino acids were measured in suspensions of human polymorphonuclear leukocytes (PMNs) under resting conditions and after various phagocytic stimuli. Both ouabain-sensitive (or pump) and ouabain-insensitive (or leak) influxes of K were determined. In 5 mM external K, mean total K influx was 0.69 nmol/10⁶ cells x min, of which 52% was ouabain-sensitive. Ouabain binding was irreversible, and, as in erythrocytes, was inhibited by K. At external concentrations of 0.1 mM, influxes of lysine and leucine were entirely carrier-mediated, with means of 0.021 nmol/10⁶ cells x min, and 0.019 nmol/10⁶ cells x min, respectively. After incubation of PMNs with zymosan or latex particles, the K pump was reduced more than 60%, whereas amino acid influxes were inhibited only by 30%. PMNs were also exposed to cytochalasin B before challenge by particles: the drug prevented phagocytosis but not surface binding of zymosan, nor did it influence transport of K or amino acids. After pretreatment of PMNs with cytochalasin B, interaction of zymosan with their surface resulted in the same degree of inhibition of influxes of K and amino acids as when the cells were permitted to phagocytose the particles. In contrast, exposure of PMN to latex particles, which do not bind to cytochalasin B-treated cells, after pretreatment of cells with cytochalasin B did not result in inhibition of influxes. Treatment of cells with colchicine had no effect on either membrane transport or its inhibition after exposure to various phagocytic stimuli. These results indicate that the surface membranes of PMNs are functionally heterogeneous with respect to the association of transport sites for the different solutes. Moreover, loss of specific membrane functions from phagocytosing cells may result from the surface-at-tachment phase of particle-cell interactions, since the interactions of zymosan particles with PMNs in the absence of phagocytosis also inhibited transport of solutes.