Histidine Uptake Research Articles

Hypoxia and ischemia modifies histamine metabolism and transport in brain synaptosomes.

Histamine level (HA), the activities of the HA synthetizing enzyme--histidine decarboxylase (HD) and HA metabolizing enzyme--histamine methyltransferase (HMT) and the uptake and release of histidine and histamine were analyzed in synaptosomal preparations obtained from rats with brain hypoxia and ischemia. Hypoxia produced only non-significant changes in all the parameters studied, whereas ischemia induced increase of both enzyme activities and histidine release, with simultaneous decreased of histidine uptake and HA level. The effect of ischemia appeared to be reversible; the changes retreated within 1 h of resuscitation together with the vital functions of rats.

Uptake of copper by mouse hepatocytes.

This study has investigated the uptake of copper by mouse hepatocytes. The cells gave similar results whether they were used right after isolation or maintained overnight on collagen-coated dishes. Uptake from cells in suspension followed two phases: an initial rapid binding followed by a linear uptake phase. The two phases were not so easily distinguishable in cells grown in culture where uptake was linear over the first hour. The uptake showed saturation but may not have followed simple kinetics. Histidine stimulated uptake in a concentration-dependent manner, as did some other amino acids, but copper had very little effect on histidine uptake. The process was not dependent on intracellular adenosine triphosphate (ATP), since inhibitors that substantially reduced ATP levels inside the cell did not alter copper uptake. The inhibitors, however, blocked histidine uptake to varying degrees, suggesting that copper and histidine are taken up by different pathways. The uptake was reduced markedly by N-ethyl maleimide, and preincubation of the cells with "Pronase" resulted in a decrease of uptake. A model for the uptake of copper by hepatocytes that incorporates the data presented in this paper with that produced by earlier workers is suggested.

Histidine transport in plasma membrane vesicles from rat liver.

The transport of L-histidine, a selective substrate for system N, across liver plasma membrane vesicles has been studied. The amino acid is accumulated sevenfold within the intravesicular space in the presence of a sodium gradient. Lithium can replace sodium to some extent in the cotransport mechanism. The amino acid translocation is not influenced by the transmembrane electrical potential difference. Histidine kinetics involves a saturable component plus a linear one both in the presence and in the absence of sodium. Sodium affects mainly the affinity of the translocator and to a lesser extent its mobility. Histidine uptake is competitively inhibited by glutamine and it is affected by alanine in a noncompetitive manner.

PH dependence of histidine affinity for blood-brain barrier carrier transport systems for neutral and cationic amino acids.

The effects of pH (3.5-7.5) on the brain uptake of histidine by the blood-brain barrier (BBB) carriers for neutral and cationic amino acids were tested, in competition with unlabeled histidine, arginine, or phenylalanine, with the single-pass carotid injection technique. Cationic amino acid ( [14C]arginine) uptake was increasingly inhibited by unlabeled histidine as the pH of the injection solution decreased. In contrast, the inhibitory effect of unlabeled histidine on neutral amino acid ( [14C]phenylalanine) uptake decreased with decreasing pH. Brain uptake indices with varying histidine concentrations indicated that the neutral form of histidine inhibited phenylalanine uptake whereas the cationic form competed with arginine uptake. Since phenylalanine decreased [14C]histidine uptake at all pH values whereas arginine did not, it was concluded that the cationic form of histidine had an affinity for the cationic carrier, but was not transported by it. We propose that the saturable entry of histidine into brain is, under normal physiological circumstances, mediated solely by the carrier for neutral amino acids.

Is neurotransmitter histamine predominantly inactivated in astrocytes?

Rat synaptosomes and astroglia cell-enriched fraction were tested for the uptake of histamine (HA) and its precursor histidine, and the activities of the HA-synthesizing enzyme, histidine decarboxylase (HD) and HA-metabolizing enzyme, histamine methyltransferase (HMT). While histidine uptake was more active into synaptosomes than into astrocytes, only astrocytes were capable of a significant HA uptake. Kinetic analysis of the astrocytic HA uptake revealed a high affinity-low capacity system ( K m = 5·10 −7 M, V max = 1.6·10 −12 mol·min −1·mg −1) similar to the astroglial transport systems for other neurotransmi HMT was 70% more active in astrocytes than in synaptosomes, whereas HD activity was not different in these two preparations. The results indicate that astrocytes could be the major site of neurotransmitter HA inactivation.

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 α-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 [(14)C]-basic amino acids. iv) Uptake of [(14)C]-glutamic acid took place only at acidic pHs. v) [(14)C]-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.

Histidine transport into rat brain synaptosomes.

Histidine transport and metabolism in rat brain synaptosomes were investigated to study the possible role of histidine uptake in the synthesis of the putative neurotransmitter histamine (HA). Histidine uptake was found to be regionally distributed and temperature sensitive, and was not totally independent of sodium or potassium ions. Transport was inhibited by metabolic inhibitors, as well as by promethazine and quinacrine. A number of other HA-related agents and several histidine metabolites had no effect. Kinetic analyses of histidine transport revealed the presence of both high- and low-affinity systems in cerebral cortex. Histidine uptake increased following preexposure of synaptosomes to depolarizing concentrations of potassium. This effect was dependent on the presence of calcium ions during the preincubation. No newly formed [3H]HA was detectable in rat brain synaptosomes following [3H]histidine transport. Lesions of the medial forebrain bundle did not alter histidine uptake in the hippocampus or cerebral cortex. Ontogenic studies indicated that the histidine uptake system developed rapidly and reached a peak during postnatal days 12-17. Overall, the present findings do not support a role for histidine transport in the regulation or maintenance of neurotransmitter pools of HA in rat brain.

Electrogenic K+-basic amino-acid cotransport in the midgut of lepidopteran larvae

Experiments performed on isolated midgut demonstrate that the model proposed for the absorption of neutral amino acids in the K+-transporting intestinal epithelium of lepidopteran larvae applies also to the transport of the basic amino acids histidine and lysine. The characteristics of these K+-basic amino-acid cotransports have been studied in brush-border membrane vesicles. Histidine and lysine are transported by different transport agencies, which share, to a different degree, a high sensitivity to transmembrane electrical potential difference. Kinetic analysis showed thatKm for histidine and lysine increased 10-fold and three-fold, respectively, whereasVmax was only slightly modified when the electrical potential difference was abolished. The relationship between potassium concentration and histidine uptake indicates a cooperative binding of more than one potassium to the transporter. Countertransport experiments with glutamine as elicitor show that histidine and glutamine are transported through the same system.

Net release or uptake of histidine and carnosine in kidney of dogs.

Previous studies are equivocal as to whether the dog kidney produces histidine. Because one possible source of renal histidine is carnosine (beta-alanyl-L-histidine), we investigated net renal production (release) or utilization (uptake) (Qmet) of histidine and carnosine in 19 female dogs after they were fed histidine-free (9 dogs) or histidine-containing diets (10 dogs). Diets were fed in short-(2-11 days) or long-term (52-57 days) studies. Dogs were infused with half-normal saline for 120 min followed by an infusion of half-normal saline containing carnosine, 50 mumol/min. Renal Qmet histidine, calculated from either plasma or whole blood values, was positive during infusion of half-normal saline. During carnosine infusion, Qmet histidine increased markedly, and there was net renal uptake of carnosine. The Qmet histidine and carnosine were not different in the dogs fed histidine-free vs. histidine-containing diets. Thus there is net renal release of histidine in female dogs that increases when carnosine is administered. Qmet histidine or carnosine do not change adaptively when dogs are fed histidine-free diets.

The histidine permease gene ( HIP1) of Saccharomyces cerevisiae

The histidine-specific permease gene ( HIP1) of Saccharomyces cerevisiae has been mapped, cloned, and sequenced. The HIP1 gene maps to the right arm of chromosome VII, approx. 11 cM distal to the ADE3 gene. The gene was isolated as an 8.6-kb BamHIW- Sau3A fragment by complementation of the histidine-specific permease deficiency in recipient yeast cells. We sequenced a 2.4-kb subfragment of this BamHI- Sau3A fragment containing the HIP1 gene and identified a 1596-bp open reading frame (ORF). We confirmed the assignment of the 1596-bp ORF as the HIP1 coding sequence by sequencing a hipl nonsense mutation. Analysis of the amino acid (aa) sequence of the HIP1 gene reveals several hydrophobic stretches, but shows no obvious N-terminal signal peptide. We have constructed a deletion of the HIP1 gene in vitro and replaced the wild-type copy of the gene with this deletion. The hipl deletion mutant can grow when it is supplemented with 30 mM histidine, 50 times the amount required for the growth of HIP1 cells. Revertants of this deletion mutant able to grow on a normal level of histidine arise by mutation in unlinked genes. Both these observations suggest that there are additional, low-affinity pathways for histidine uptake.

Transport of carnosine by mouse intestinal brush-border membrane vesicles

The characteristics of carnosine (β-alanyl- l-histidine) transport have been studied using purified brush-border membrane vesicles from mouse small intestine. Uptake curves did not exhibit any overshoot phenomena, and were similar under Na +, K + or choline + gradient conditions (extravesicular > intravesicular). However, uptake of histidine showed an overshoot phenomenon in the presence of a Na +-gradient. There was no detectable hydrolysis of carnosine during 15 min of incubation with membrane vesicles under conditions used for transport experiments. Analysis of intravesicular contents further showed the complete absence of the constituent free amino acids of carnosine, and indicates that intact carnosine is transported. Studies on the effect of concentration on peptide uptake revealed that transport occurred by a saturable process conforming to Michaelis-Menten kinetics with a K m of 9.6 ± 1.4 mM and a V max of 2.9 ± 0.2 nmol / mg protein per 0.4 min. Uptake of carnosine was inhibited by both di- and tripeptides with a maximum inhibition of 68% by glycyl- l-leucyltyrosine. These results clearly demonstrate that carnosine is transported intact by a carrier-mediated, Na +-independent process.

The nature of the sodium dependence of amino acid transport by system A of the S37 cell

The present study was undertaken to answer a specific question: is the activity of amino acid transport system A entirely abolished in the absence of sodium in the medium, or does some residual activity of system A remain? A biphasic double-reciprocal plot was obtained for histidine uptake from media in which sucrose, potassium ion, or choline replaced sodium ion. The uptake of labeled N-methyl-2-amino isobutyric acid or labeled histidine from sodium-free media was inhibited by added N-methyl-2-amino isobutyric acid. N-methyl-2-amino isobutyric acid also inhibited transport of labeled alanine when system L was already blocked in a choline chloride medium. Concentrative uptake of N-methyl-2-amino isobutyric acid or alanine occurred in a choline chloride medium. Uptake of N-methyl-2-amino isobutyric acid was saturable in the absence of sodium ion, but was stimulated by the presence of sodium ion. A non -saturable uptake route was not detectable in the S37 cell. The activity of amino acid transport system A in the S37 cell is clearly enhanced by the presence of sodium ion, but sodium ion is not an obligatory requirement for transfer of amino acids through system A to occur.

Neutral amino acid transport by plasma membrane vesicles of the rabbit choroid plexus

Uptakes of neutral l-amino acids into rabbit choroid plexus apical membrane vesicles were studied using l-[ 14C]amino acids. Apical membrane vesicles were prepared using Ca 2+ precipitation and uptakes of 14C-labeled substrates were measured by a rapid mixing and filtration procedure. Na-dependent, concentrative uptake was observed for proline, histidine and methylaminoisobutyric acid (MeAIB). Phenylalanine and d-glucose uptakes showed no significant Na dependence. Proline uptake was a saturable function of the proline concentration with J max 3.5 nmol/(mg min) and K t 0.3 mM. Competition experiments in the presence of Na indicated that proline and MeAIB are mutually competetive. Proline uptake was also inhibited 25% by phenylalanine, but MeAIB uptake was relatively unaffected. Neither proline nor MeAIB transport was significantly inhibited by glycine. We conclude that proline uptake across rabbit choroid plexus apical membrane vesicles is via an Na-dependent pathway which is shared by MeAIB and, to a minor extent, by phenylalanine, but from which glycine is excluded. Histidine uptake was inhibited by glycine, GABA, phenylalanine, proline and MeAIB. This suggests that histidine may utilize a different pathway in addition to that shared with proline and MeAIB. These transporters should play an active role in the regulation of amino acids in the CSF.

Mobilization of copper(II) from plasma components and mechanisms of hepatic copper transport.

The effects of plasma Cu(II) ligands on the kinetics of Cu(II) transport by rat liver parenchymal cells were determined to examine how Cu(II) is mobilized from plasma and transported into liver cells. Albumin markedly inhibited Cu(II) uptake at Cu(II)-to-albumin molar ratios of 3:1 or less. Kinetic analyses showed that albumin inhibits Cu(II) uptake by reducing the concentration of free Cu(II) in solution. Under conditions of excess albumin to Cu(II), histidine facilitated albumin-inhibited uptake of Cu(II). Threonine, glutamine, and most other amino acids were without effect. Moreover, the facilitation effect of a low-molecular-weight plasma fraction (less than or equal to 5,000) was largely accounted for by its histidine concentration. The tripeptide Gly-His-Lys also inhibited Cu(II) uptake into hepatocytes by the same mechanism as albumin. The inhibitory effects of albumin and Gly-His-Lys were additive with or without histidine. The active species in the Cu(II), albumin, and histamine mixtures was shown to be the His2Cu(II) complex. Vmax for this complex was identical to the Vmax for free Cu(II), but the Km was slightly higher [15 microM vs. 11 microM for free Cu(II)]. Concurrent determinations of [3H]-histidine and 64Cu(II) uptake showed that histidine was not transported with Cu(II) from His X Cu(II) or His2Cu(II) complexes. The data are consistent with histidine mobilizing Cu(II) from albumin by competing for Cu(II), interaction of the His2Cu(II) complex with the putative hepatic copper transport protein, and transport of copper as free ionic copper.

Comparison of system N in fetal hepatocytes and in related cell lines.

In contrast to the changes seen in membrane transport systems for other neutral, anionic, and cationic amino acids, System N for glutamine, histidine, and asparagine in the rat hepatocytes shows nearly constant properties at the fetal, differentiated, and cultured hepatoma stages. These properties were tested by measuring the Na+-dependent transport of glutamine. This approximate constancy applies not only to the transport selectivity of the system among neutral amino acids, but also to its tolerance of Li+ as a substitute for Na+, its characteristic sensitivity to pH lowering, its relative sensitivity to N-ethylmaleimide, its stimulation by amino acid deprivation, and its failure to respond to insulin or glucagon. The properties of histidine as a substrate for System N were also examined. Inhibition studies with different cell types suggest that the Na+-dependent glutamine and histidine uptake is more restricted to System N in the hepatoma line H35 (H4-11-EC,3) and in the fetal hepatocyte than in hepatoma line HTC and the Ehrlich cells. The Na+-independent component of glutamine and histidine uptake was greater in the hepatoma cells in continuous culture than in fetal and adult hepatocytes in primary culture. Trans-stimulation of glutamine and histidine influx into H35 cells occurs predominantly by the Na+-independent route.

Histidine uptake by isolated rat peritoneal mast cells. Effect of inhibiton of histidine decarboxylase by α-fluoromethylhistidine

Preincubation with ( S)- α-fluoromethylhistidine, an irreversible inhibitor of histidine decarboxylase, was found to markedly reduce, but not eliminate, the uptake of [ 3H]histidine by rat peritoneal mast cells. The V max for histidine transport for cells in which decarboxylation of histidine had been completely inhibited was 11.9 pmoles per min per 10 6 cells, compared to a V max of 18.9 pmoles per min per 10 6 cells in the presence of active mast cell histidine decarboxylase. The K m of uptake was 139 μM in the presence of α-fluoromethylhistidine, several times higher than the K m of 44.0 μM in the uninhibited cell. α-Fluoromethylhistidine did not inhibit mast cell uptake of phenylalanine, a competitive inhibitor of histidine uptake but not a substrate for histidine decarboxylase; nor did it inhibit the uptake of histidine by non-mast cells, which lack histidine decarboxylase. Levels of intracellular [ 3H]histidine in mast cells were similar in the presence and absence of the decarboxylase inhibitor. Based on these observations, we propose that intracellular decarboxylation of histidine in the mast cell serves to specifically enhance the uptake of histidine by the relatively non-specific amino acid transporter present in the plasma membrane of the cell.

Histidine utilization by Alcaligenes eutrophus: Regulation of histidase formation under heterotrophic conditions of growth

Histidine supported good growth of Alcaligenes eutrophus strain H 16 as a nitrogen source, but only poor growth as a carbon and energy source. The facultative chemolithoautotrophic bacterium was also able to utilize urocanic acid, the first intermediate of histidine catabolism. The products of histidine degradation were ammonium, formate and glutamate. Three enzymes of the pathway, histidase, urocanase and formiminoglutamate hydrolase, were present in histidine-grown cells. Two types of spontaneous mutants, derived from the wild type, were characterized by an increased growth rate on histidine. One of these types was found to produce histidase constitutively and at a higher activity compared with the parental strain. The second type of mutant had apparently gained an improved histidine uptake system, which is supposed to be growth rate-limiting in the wild type. From the physiological studies the conclusion was drawn that the control of histidine-degrading enzymes is based on induction by urocanate and catabolite repression by carbon sources supporting fast growth, such as succinate or pyruvate. Ammonium was found not to affect catabolite repression, however, we obtained evidence that histidine uptake is subject to a nitrogen control.

Effect of purine nucleotides and other compounds on the uptake of histamine and histidine.

The uptake of 14C-ring labelled histamine and histidine was studied in human and guinea-pig leucocytes, and in rat peritoneal mast cells. Histamine uptake by sensitized human leucocytes was partly released by antigen or anti-IgE challenge, suggesting that histamine is taken up by the same cells that synthesize and secrete that amine, i.e. basophils. Histamine antagonists, particularly of the H2-subclass, had an inhibitory effect, but histamine agonists had a relatively small and inconsistent effect. Adrenoceptor stimulants and phosphodiesterase inhibitors produced small effects, but dibutyryl cAMP at a concentration of 4-10 mM consistently increased histamine uptake by more than 100% during a 30 min incubation. By contrast, ATP exerted an inhibitory effect, starting at a concentration of 0.2 mM and reaching a maximum (90% inhibition) at 10 mM. Histidine uptake was inhibited by ATP and slightly stimulated by cAMP. Propranolol caused stimulation of histamine uptake and inhibition of histidine uptake at micromolar concentrations. These results suggest that the uptake of histamine is not due to simple diffusion. Although it does not contribute significantly to total cell histamine content or to the removal mechanism of extracellular histamine, it may contribute to the auto-regulatory processes modulating histamine release, synthesis and metabolism. It may also have a significant effect on the extracellular level of histamine, under the influence of drugs or in pathological states.

Histamine synthesis in intact and disrupted rat mast cells

Histamine production by purified intact rat peritoneal mast cells, as measured by formation of [β- 3H]histamine from [β- 3H] l-histidine or by release of 14CO 2 from 14C-carboxyl-labeled histidine, was ten to thirty times greater than that of disrupted cells or soluble extracts of these cells. Loss of activity was evident whether cells were disrupted by sonification, freezing and thawing, or lysis, both in the absence and presence of inhibitors of proteolytic enzymes and agents known to preserve enzyme activity. Studies with decarboxylase inhibitors indicated that a specific histidine decarboxylase was responsible for histamine formation in both the intact cells and cell extracts. In the presence of subsaturating concentrations of histidine, various histidine analogs and glutamine inhibited histidine uptake and histamine formation in intact mast cells but did not inhibit synthesis in cell extracts. These data indicate that, at physiological concentrations of histidine, blockade of histidine transport (through system N) may limit histamine synthesis in the intact cell and that measurement of histidine decarboxylase activity in tissue homogenates or cell extracts may not reflect actual histidine decarboxylase activity in vivo.

Interaction of 2-aminobicyclo[3.2.1]octane-2-carboxylic acid with the amino acid transport systems of the sarcoma 37 murine ascites tumor cell.

The relatively broad and overlapping specificities of amino acid transport systems have made the synthesis of analogues specific to single transport systems desirable. The analogue in general use as a specific substrate for transport system L has been 2-aminobicyclo[2.2.1]heptane-2-carboxylic acid (BCH). The affinity of BCH for the binding site of system L has been shown to be less than that of the natural substrate, leucine. Earlier studies from this laboratory suggested that higher homologues in a series could have greater affinity for system L. A higher homologue of BCH, 2-aminobicyclo[3.2.1]octane-2-carboxylic acid (ABOCA), has been synthesized and studied as a substrate and competitor for amino acid transport systems of the sarcoma 37 (S37) ascites cell. ABOCA inhibited the transport system dominant in the low concentration region for histidine uptake (system L) but had no effect on the uptake of labeled N-methyl-alpha-aminoisobutyric acid (MeAIB). MeAIB had no effect on labeled ABOCA uptake in S37 cells. ABOCA inhibited the uptakes of labeled leucine and labeled BCH competitively. Leucine, histidine, and BCH inhibited the uptake of labeled ABOCA competitively. Typical L system substrates demonstrated exchange effects with labeled ABOCA. The b isomer of ABOCA demonstrated slightly greater affinity for system L than did the a isomer. We conclude that ABOCA is an analogue restricted to interaction with amino acid transport system L, that it has greater affinity for system L than does BCH, and that its selection for system l is determined principally by an apolar interaction with steric considerations secondary.