Transport of basic amino acids in Riccia fluitans: Evidence for a second binding site

The transport of several amino acids with different side-chain characteristics has been investigated in the aquatic liverwort Riccia fluitans. i) The saturation of system I (neutral amino acids) by addition of excess -aminoisobutyric acid to the external medium completely eliminated the electrical effects which are usually set off by neutral amino acids. Under these conditions arginine and lysine significantly depolarized the plasmalemma. ii) L- and D-lysine/arginine were discriminated against in favour of the L-isomers. iii) Increasing the external proton concentration in the interval pH 9 to 4.5 stimulated plasmalemma depolarization, electrical net current, and uptake of [¹⁴C]-basic amino acids. iv) Uptake of [¹⁴C]-glutamic acid took place only at acidic pHs. v) [¹⁴C]-histidine uptake had an optimum between pH 6 and 5.5. vi) Overlapping of the transport of basic, neutral, and acidic amino acids was common. It is suggested that besides system I, a second system (II), specific for basic amino acids, exists in the plasmalemma of Riccia fluitans. It is concluded that the amino-acid molecule with an uncharged side chain is the substrate for system I, which also binds and transports the neutral species of acidic amino acids, whereas system II is specific for amino acids with a positively charged side chain. The possibility of system II being a proton cotransport is discussed.Abbreviation AiB -aminoisobutyric acid     

Amino acid transport and protein synthesis in energetically-stable calcium-tolerant isolated cardiac myocytes

Myocytes isolated by enzymic dispersion from adult rat ventricular tissue are shown to be energetically stable in the presence of 0.5 mM CaCl₂. ATP and ADP content and rates of lactate production are comparable with those of intact myocardial tissue and consistent with these cells being tightly coupled. Addition of 2,4-dinitrophenol precipitates rapid changes in adenine nucleotide concentrations and a 10-fold increase in lactate production. Cardiac myocytes selectively transport neutral amino acids of the A and L classes. Transport of the amino acid analogue α-aminoisobutyric acid is an active, temperature-dependent and insulin-sensitive process. The apparent K_m for α-aminoisobutyric acid transport is similar to that determined for embryonic cardiac cells. Mature myocytes incorporate labelled amino acids into cytoplasmic proteins with molecular weights ranging from 10 000 to 150 000. Newly synthesised protein is metabolically stable. The data establishes calcium-tolerant myocytes as an experimental system offering many advantages over whole hearts for short- and long-term studies of protein synthesis and catabolism.     

Steady-state current-voltage characteristics of amino acid transport in rhizoid cells of Riccia fluitans Is the carrier negatively charged?

The amino acid transport across the plasmalemma of Riccia fluitans rhizoid cells has been further characterized by means of current-voltage $\text{I?V}$) analysis. On the basis of two cyclic transport models which include six different carrier states, the question is raised, whether the electrochemical pH-gradient drives a negatively charged carrier or a positively charged alanine-proton-carrier complex across the membrane. $\text{I?V}$ analysis shows that (1) the typical $\text{I?V}$ characteristic of l-alanine transport follows a sigmoid curve, (2) maximal accumulation of l-alanine within the cytoplasm is reached after about 1 hour, (3) the electrically accessible cytoplasmic l-alanine concentration is limited to about 20 mM, and (4) the steady-state saturation current depends directly on external l-alanine concentration. It is concluded that (a) these results are consistent with the predictions of the models for a negatively charged carrier, and (b) that the rate-limiting step involves the translocation of the ternary complex.     

Implications for cytoplasmic pH,protonmotice force,and amino-acid transport across the plasmalemma of Riccia fluitans

By means of pH-sensitive microelectrodes, cytoplasmic pH has been monitored continuously during amino-acid transport across the plasmalemma of Riccia fluitans rhizoid cells under various experimental conditions. (i) Contrary to the general assumption that import of amino acids (or hexoses) together with protons should lead to cytoplasmic acidification, an alkalinization of 0.1–0.3 pH_c units was found for all amino acids tested. Similar alkalinizations were recorded in the presence of hexoses and methylamine. No alkalinization occurred when the substrates were added in the depolarized state or in the presence of cyanide, where the electrogenic H⁺-pump is inhibited. (ii) After acidification of the cytoplasm by means of various concentrations of acetic acid, amino-acid transport is massively altered, although the protonmotive force remained essentially constant. It is suggested that H⁺-cotransport is energetically interconnected with the proton-export pump which is stimulated by the amino-acid-induced depolarization, thus causing proton depletion of the cytoplasm. It is concluded that, in order to investigate H⁺-dependent cotransport processes, the cytoplasmic pH must be measured and be under continuous experimental control; secondly, neither pH nor the protonmotive force across a membrane are reliable quantities for analysing a proton-dependent process.Abbreviations 3-OMG 3-oxymethylglucose - pH_c cytoplasmic pH - _m electrical potential difference across the respective membrane, i.e. membrane potential - _H+/F (=pmf) electrochemical proton gradient     

Sodium dependence of maximum flux, JM, and Km of amino acid transport in Ehrlich ascites cells

The Michaelis-Menten parameters, J_M and K_m of the initial 1-min fluxes of uptake of l-phenylalanine and of α-aminoisobutyric acid were determined for extracellular concentrations of Na⁺ ranging from 0.5 to 110 mequiv/l for Ehrlich ascites tumor cells. The maximal initial flux, J_M, decreased with decrease in extracellular Na⁺ for both α-aminoisobutyric acid and phenylalanine but the K_m for α-aminoisobutyric acid increased markedly as the Na⁺ concentration fell whereas the K_m for phenylalanine decreased. Cycloleucine behaved like phenylalanine.The data provides strong evidence that the Na⁺-independent flux of phenylalanine is an exchange diffusion flux that can be varied by changing the intracellular level of amino acids such as phenylalanine. For phenylalanine, cyclolcucine, and methionine this exchange diffusion flux appears to be additive with the Na⁺-dependent initial flux. α-Aminoisobutyric acid also has an exchange diffusion that is Na⁺-independent but it has a high K_m and is not additive with the Na⁺-dependent flux.     

Effects of chelating agents on the initial interaction of phytohemagglutinin with lymphocytes and the subsequent stimulation of amino acid uptake

The chelating agents, ethylene glycol bis-(β-aminoethyl ether)-N,N′-tetraacetic acid (EGTA) and EDTA, had no effect on the initial interaction of phytohemagglutinin with lymphocytes at concentrations which have been shown previously to inhibit the development of the phytohemagglutinin response completely. However, they had a marked inhibitory effect on uptake of the amino acid analog, α-aminoisobutyric acid in both unstimulated and phytohemagglutinin-stimulated cells. The inhibition of amino acid uptake by EGTA could be reversed by adding Ca²⁺ but not Mg²⁺. These results demonstrated that Ca²⁺ is not essential to the initial interaction of phytohemagglutinin with the cell, but does influence amino acid transport which may be a critical preparatory event for later increased protein synthesis.     

Evidence for amino Acid-h co-transport in oat coleoptiles

Microelectrode and tracer techniques were used to test for possible amino acid-H⁺ co-transport in coleoptiles of Avena sativa L. cv. “Garry.” The amino acid analogue α-aminoisobutyric acid (AIB) caused transient depolarization of the membrane potential. The absolute magnitude of the maximum depolarization was affected by the same factors that affected AIB transport. Both increased with higher concentrations of AIB, increased with higher acidities in the medium, and were enhanced by indoleacetic acid (which hyperpolarized the membrane potential). AIB transport was reduced as K⁺ concentrations in the medium were increased and by the metabolic inhibitor NaN₃, both of which reduce membrane potentials. Our data fit an amino acid-H⁺ co-transport model in which transport is controlled by both the membrane potential and proton concentration components of the chemical potential difference of protons across the coleoptile cell membrane.     

Transport of leucine in the cyanobacterium Anabaena variabilis

The amino acid leucine was transported by the cyanobacterium Anabaena variabilis. The K _m for transport was 10.8 M; the V _max was 8.7 nmoles min^–1 mg^–1 chlorophyll a. Transport of leucine was energy dependent: uptake of leucine was inhibited in the dark, and by DCMU and cyanide. Transport was neither dependent on nor enhanced by Na⁺. Prior growth of cells with leucine did not repress transport of [¹⁴C]-leucine. Alanine, glycine, valine, and methionine were strong competitive inhibitors of leucine uptake; serine, threonine, isoleucine, norleucine, and d-alanine competitively inhibited to a lesser degree. Other amino acids or amino acid analogues, including d-leucine, -aminoisobutyrate, and d-serine did not inhibit the transport of leucine.Abbreviations Chl a chlorophyll a - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - TES N-tris(hydroxymethyl)-2-aminoethane-sulfonic acid - TCA trichloroacetic acid - Tris N-tris(hydroxymethyl)aminoethane     

Amino-acid absorption by developing herring eggs

¹⁴C-glycine absorption by eggs of the herringClupea harengus from a 2 µM solution at 15°C depends on the stage of embryonic development. Unidirectional¹⁴C-glycine influx rates are small at early stages: 0.6 ± 0.1 and 0.5 ± 0.1 pmoles egg^–1 h^–1 in embryos 5 h and 28 h after fertilization, respectively. They increase drastically about 51 h after fertilization (prior to blastopore closure) to 3.7 ± 0.9 pmoles egg^–1 h^–1. Glycine uptake steadily continues to increase almost until hatching (maximum values = 18.8 ± 2.7 pmoles egg^–1 h^–1), decreasing slightly prior to hatching. Distribution ratios (radioactivity µl^–1 of egg volume: radioactivity µl^–1 ambient medium) exceed the equilibrium ratio of 1 between 51 h and 78 h after fertilization, reaching values of 4.7 two days prior to hatching, thus suggesting the presence of a transport mechanism capable of transferring the amino acid against the concentration gradient. Curves for concentration-dependent¹⁴C-glycine and¹⁴C--aminoisobutyric acid absorption are very similar; they consist of a linear portion at higher concentrations and a saturable component, indicating a mediated uptake process. Calculations performed by means of aminoacid absorption rates and O₂ uptake data suggest that herring eggs scarcely obtain nutritional benefits from absorption of dissolved amino acids in natural spawning areas.     

Loss of membrane transport ability in leaf cells and release of protein as a result of osmotic shock

Osmotic shock severely reduces the ability of aged strips of Phaseolus vulgaris leaves to take up α-aminoisobutyric acid, an amino acid analogue which is known to be transported by a specific mechanism. Cold osmotic shock, i.e., transfer from 0.5 m sucrose at 25 C to H₂O at 2 C, decreases α-aminoisobutyric acid uptake almost to zero. Substitution of 10⁻³m ethylenediaminetetraacetate for the sucrose, i.e., treatment which does not involve plasmolysis, produces a similar, but less severe, effect.     

Procedure for the sample preparation and handling for the determination of amino acids, monoamines and metabolites from microdissected brain regions of the rat

A method is described for the analysis of amino acids, monoamines and metabolites by high-performance liquid chromatography with electrochemical detection (HPLC–ED) from individual brain areas. The chromatographic separations were achieved using microbore columns. For amino acids we used a 100×1 mm I.D. C₈, 5 μm column. A binary mobile phases was used: mobile phase A consisted of 0.1 M sodium acetate buffer (pH 6.8)–methanol–dimethylacetamide (69:24:7, v/v) and mobile phase B consisted of sodium acetate buffer (pH 6.8)–methanol–dimethylacetamide (15:45:40, v/v). The flow-rate was maintained at 150 μl/min. For monoamines and metabolites we used a 150×1 mm I.D. C₁₈ 5 μm reversed-phase column. The mobile phase consisted of 25 mM monobasic sodium phosphate, 50 mM sodium citrate, 27 μM disodium EDTA, 10 mM diethylamine, 2.2 mM octane sulfonic acid and 10 mM sodium chloride with 3% methanol and 2.2% dimethylacetamide. The potential was +700 mV versus Ag/AgCl reference electrode for both the amino acids and the biogenic amines and metabolites. Ten rat brain regions, including various cortical areas, the cerebellum, hippocampus, substantia nigra, red nucleus and locus coeruleus were microdissected or micropunched from frozen 300-μm tissue slices. Tissue samples were homogenized in 50 or 100 μl of 0.05 M perchloric acid. The precise handling and processing of the tissue samples and tissue homogenates are described in detail, since care must be exercised in processing such small volumes while preventing sample degradation. An aliquot of the sample was derivatized to form the tert.-butylthiol derivatives of the amino acids and γ-aminobutyric acid. A second aliquot of the same sample was used for monamine and metabolite analyses. The results indicate that the procedure is ideal for processing and analyzing small tissue samples.     

The Regulation of Proton/Amino Acid Symport in Riccia fluitans L. by Cytosolic pH and Proton Pump Activity

In the aquatic liverwort Riccia fluitans the regulation of theplasma membrane H⁺/amino acid symport has been investigated.Cytosolic pH (pH_c), membrane potential (E_m) and membrane conductancehave been measured and related to transport data, (i) The releaseof [¹⁴C]amino acids is strongly stimulated by cytosolic acidification,induced by the external addition of acetic acid, a decreasein external K⁺, and in the change from light to dark. On average,a decrease in pHc of 0.5 to 0.6 units corresponded with a 4-foldstimulation in amino acid efflux. (ii) External pH changes havefar less effect on substrate transport than the cytosolic pHshifts of the same order. (iii) The inwardly directed positivecurrent, induced by amino acids, is severely inhibited by cytosolicacidification. (iv) Fusicoccin (FC) stimulates amino acid uptakewithout considerable change in proton motive force. (v) Whenthe proton motive force is kept constant, the uptake of aminoacids into Riccia thalli is much lower than when the pump isdeactivated. It is suggested that both the proton pump activityand cytosolic pH are the dominant factors in the regulationof the H⁺/amino acid symport across the plasma membrane of Ricciafluitans, and it is concluded that the proton motive force isnot a reliable quantity to predict and interpret transport kinetics. Key words: Amino acid, cytosolic pH, pH-sensitive electrode, proton motive force, regulation, Riccia fluitans     

Amine transport at the plasmalemma of Riccia fluitans

Green thallus cells of the aquatic liverwort, Riccia fluitans, are rapidly depolarized in the presence of 1–20 μM NH₄Cl and 5–100 μM CH₃NH₃Cl, respectively. Simultaneously, the membrane conductance is increased from 0.41 to 1.2 S · m^?2. Uptake of [¹⁴C]methylamine is stimulated by increasing [K⁺]_o and inhibited by increasing [Na⁺]_o or [H⁺]_o, is highly voltage sensitive, and saturates at low amine concentrations.Double-reciprocal plots of (a) maximal membrane depolarization and (b) methylamine uptake vs. external amine concentration give apparent K_m values of 2 ± 1 μM ammonia and 25–50 μM methylamine; K_m values for changes in conductance and membrane current are greater and voltage dependent. Whereas the amine transport into the cell is strongly inhibited by CN^?, the amine efflux is stimulated.The current-voltage characteristics of the ammonia transport are represented by a sigmoid curve with an equilibrium potential of ?60 mV, and this is understood as a typical carrier curve with a saturation current of about 70 mA · m^?2. It is further concluded that the evidently carrier-mediated transport is competitive for the two amines tested, and that ammonia and methylamine are transported in the protonated form as NH₄⁺ and CH₃NH₃⁺ into the cytoplasm.     

Changes in amino acid content of an algal feed species (Navicula sp.) and their effect on growth and survival of juvenile abalone (Haliotis rubra)

The growth and survival of juvenile Haliotis rubra, when fed with the diatom Navicula sp. cultured in f/2 medium containing combined nitrogen at 24.71 mg NO₃-N L^–1 (high), 12.35 mg NO₃-N L^–1 (standard) or 2.47 mg NO₃-N L^–1 (low), were compared in a 33-day trial. The alga in the low nitrogen medium contained 37% less total amino acid than that in the high and standard nitrogen media. There was a slightly greater reduction in essential amino acids (40%) compared to non-essential amino acids (35%). Juvenile abalone feeding on Navicula grown in medium with low nitrate and lower total amino acid content grew more slowly than when fed on the same species grown in standard or higher nitrogen medium with a higher amino acid content. The growth rate of juveniles was highest (43 m d^–1) in the high nitrate treatment followed (40 m d^–1) by the standard nitrate treatment and lowest (31 m d^–1) in the low nitrate treatment. The survival of the juveniles was also effected by the diet. Survival was better in the high and standard nitrogen media (88%) than the low nitrogen medium (75%). The results suggest that in order to achieve uniformity in nutritional quality of diatoms and good growth of abalone juveniles in commercial abalone nurseries, the nitrogen concentration in tanks should be monitored and additional nitrate added to provide an optimum concentration of between 2 and 12 mg NO₃-N L^–1.     

Iron accumulation on the cell wall of the aquatic moss Drepanocladus fluitans in an acid lake at pH 3.4–3.8

Iron accumulation was studied in shoots of the aquatic moss Drepanocladus fluitans (Hedw.) Warnst collected from an acid lake and stream. The concentration of iron in the shoots of the moss from Lake Usoriko (pH 3.4–3.8) increased from the tip toward the base and ranged from 0.07 to 10% on a dry weight basis. The iron concentration in the lake water was 0.15 mg 1^–1. In contrast, iron concentration in the shoots of D. fluitans from Kashiranashigawa stream (pH 4.2–4.7), one of the streams flowing into Lake Usoriko, was only 0.02 mg g^–1 at the shoot tip and 0.3% at the shoot base, while that in the stream water was <0.02 mg 1^–1. Transmission electron microscopy using a X-ray microanalyzer (TEM-XMA) study revealed accumulation of needle-like iron crystals on the cell wall and decomposed cell components. In addition, many rod-type bacteria were found in the accumulated iron deposits.The accumulation of iron in the shoots of D. fluitans is due to two processes: biological accumulation of essential iron dissolved in acid water, and abiological crystal growth on the surface of organic particulate material including the cell wall.     

Proton Gradient Across the Tonoplast of Riccia fluitans as a Result of the Joint Action of Two Electroenzymes

Using pH-sensitive microelectrodes (in vitro) and acridine orange photometry (in vivo), the actions of the two tonoplast phosphatases, the tp-ATPase and the tp-PPase, were investigated with respect to how effectively they could generate a transtonoplast pH-gradient. Under standard conditions the vacuoles of the aquatic liverwort Riccia fluitans have an in vivo pH of 4.7 to 5.0. In isolated vacuoles a maximal vacuolar pH (pH_v) of 4.74 ± 0.1 is generated in the presence of 0.1 millimolar PP_i, but only 4.93 ± 0.13 in the presence of 2.5 millimolar ATP. Both substrates added together approximate the value for PP_i. Cl⁻-stimulates the H⁺-transport driven by the tp-ATPase, but has no effect on the tp-PPase. The transport activity of the tp-ATPase approximates saturation kinetics (K_½ ≈ 0.5 millimolar), whereas transport by the tp-PPase yields an optimum around 0.1 millimolar PP_i. The transtonoplast pH-gradient is dissipated slowly by weak bases, from which a vacuolar buffer capacity of roughly 300 to 400 millimolar/pH_v unit has been estimated. From the free energy (−11.42 kilojoules per mole) for the hydrolysis of PP_i under the given experimental conditions, we conclude that the PPase-stoichiometry (transported H⁺ per hydrolyzed substrate molecule) must be 1, and that in vivo this enzyme works as a H⁺-pump rather than as a pyrophosphate synthetase.     

RNA Affinity for Molecular L-Histidine; Genetic Code Origins

Selection for affinity for free histidine yields a single RNA aptamer, which was isolated 54 times independently. This RNA is highly specific for the side chain and binds protonated L-histidine with 10²−10³-fold stereoselectivity and a dissociation constant (K_D) of 8–54 μM in different isolates. These histidine-binding RNAs have a common internal loop–hairpin loop structure, based on a conserved RAAGUGGGKKN_0–36 AUGUN_0–2AGKAACAG sequence. Notably, the repetitively isolated sequence contains two histidine anticodons, both implicated by conservation and chemical data in amino acid affinity. This site is probably the simplest structure that can meet our histidine affinity selection, which strengthens experimental support for a “stereochemical” origin of the genetic code.[Reviewing Editor: Niles Lehman]     

Differential glycosylation of N-POMC regulates the production of γ3-MSH by purified pro-opiomelanocortin converting enzyme A possible mechanism for tissue-specific processing

The amino terminus of bovine pro-opiomelanocortin (N-POMC^1–77) is partially processed in the intermediate lobe of the pituitary to N-POMC^1–49 and lys-γ₃ -melanotropin. Two pools of N-POMC^1–77 were isolated which were differentially glycosylated at threonine⁴⁵, while N-POMC^1–49 isolated from bovine intermediate lobe extracts existed in a non-glycosylated form. This suggested that differential O-linked glycosylation of N-POMC^1–77 may regulate cleavage at the Arg⁴⁹-Lys⁵⁰ processing site. We tested this hypothesis by incubating N-POMC^1–77 glycoforms with purified pro-opiomelanocortin converting enzyme. Only non-O-glycosylated N-POMC^1–77 and O-glycosylated N-POMC^1–77 with truncated oligosaccharide sidechains were sensitive to cleavage and generated predominantly lys-γ₃ -melanotropin, identified by high-performance liquid chromatography. These data provide the first functional evidence to support a role for differential O-linked glycosylation in the regulation of the processing of the N-terminus of bovine POMC.     

Transport and metabolic effects of α-aminoisobutyric acid in saccharomyces cerevisiae

α-Aminoisobutyric acid is actively transported into yeast cells by the general amino acid transport system. The system exhibits a K_m for α-aminoisobutyric acid of 270 μM, a V_max of 24 nmol/min per mg cells (dry weight), and a pH optimum of 4.1–4.3. α-Aminoisobutyric acid is also transported by a minor system(s) with a V_max of 1.7 nmol/min per mg cells. Transport occurs against a concentration gradient with the concentration ratio reaching over 1000:1 (in/out). The α-aminoisobutyric acid is not significantly metabolized or incorporated into protein after an 18 h incubation. α-Aminoisobutyric acid inhibits cell growth when a poor nitrogen source such as proline is provided but not with good nitrogen sources such as NH₄⁺. During nitrogen starvation α-aminoisobutric acid strongly inhibits the synthesis of the nitrogen catabolite repression sensitive enzyme, asparaginase II. Studies with a mutant yeast strain (GDH-CR) suggest that α-aminoisobutyric acid inhibition of asparaginase II synthesis occurs because α-aminoisobutyric acid is an effective inhibitor of protein synthesis in nitrogen starved cells.