Beta-alanine transport in synaptic plasma membrane vesicles from rat brain. Efflux, exchange and stoichiometry

The efflux and exchange of beta-alanine were studied in synaptic plasma membrane vesicles from rat brain. The mechanism of beta-alanine translocation has been probed by comparing the ion dependence of net efflux to that of exchange. Dilution-induced efflux requires the simultaneous presence of internal sodium and chloride ions while influx is dependent on the presence of these two ions on the outside [Zafra, F., Aragón, M. C., Valdivieso, F. and Giménez, C. (1984) Neurochem Res. 9, 695-707]. These data show that the release of beta-alanine occurs via the carrier system and that it is cotransported with sodium and chloride ions. beta-Alanine efflux from the membrane vesicles is stimulated by external beta-alanine. This exchange does not require external sodium and chloride but it is dependent on the external concentration of beta-alanine. Half-maximal stimulation is obtained at a beta-alanine concentration similar to the Km for beta-alanine influx. Results of the direct measurements of the coupling of sodium and chloride to the transport of beta-alanine by using a kinetic approach allow us to propose a stoichiometry for the translocation cycle catalyzed by the beta-alanine transporter of three sodium ions and one chloride ion per beta-alanine zwitterion. To account for all the observed effects of external ions, beta-alanine concentrations and membrane potential on beta-alanine influx and efflux, a kinetic model of the Na+/Cl-/beta-alanine cotransport system is discussed.     

Isolation and Properties of a β-Alanine Transaminaseless Mutant of Pseudomonas fluorescens

beta-Alanine catabolism in Pseudomonas fluorescens is initiated by the enzyme beta-alanine transaminase. We have isolated mutants which fail to produce this enzyme and thus cannot grow on beta-alanine as the sole nitrogen source. The accumulation of beta-alanine-1-(14)C has been studied in one of these mutants, strain 67, and in the wild type. In the mutant, beta-alanine remains in a stable intracellular pool, whereas in the wild type conversion of beta-alanine to an intermediate, presumably malonate semialdehyde, and to CO(2) can be detected. The membrane transport system for beta-alanine can be conveniently studied in this transaminaseless mutant.     

Release of beta-alanine from the frog skeletal muscle determined by thin-layer chromatography

The release of beta-alanine from the resting and contracting frog sartorius muscles was demonstrated by the two-dimensional thin-layer chromatography. The release of beta-alanine from indirectly stimulated muscles of frogs in winter was about 230% higher than at rest. When synaptic transmission was blocked by d-tubocurarine the release of beta-alanine from directly stimulated muscles did not exceed the release at rest. Thus, activation of neuromuscular synapse leads to increased beta-alanine release from contracting muscle.     

Beta-alanine transport in the isolated hepatocytes of the elasmobranch Raja erinacea

Cells were isolated from the liver of the skate and the uptake of beta-alanine followed using [14C]-beta-alanine. The isolated hepatocytes showed good viability, were found to accumulate beta-alanine from the incubation medium, and did so in a manner indicating a transport system involving a saturable carrier. The data for the rate of beta-alanine uptake suggest that this may be a rate-limiting step in the oxidation of the amino acid by the liver. Experiments indicated that the transport system could distinguish beta-alanine from certain structurally similar molecules (L-alanine and taurine, but not gamma-amino butyrate). Cells isolated from fish adapted to a diluted environment (50% seawater) showed no significant change in the uptake rate. However, evidence indicates that, over the range of beta-alanine concentrations occurring in the fish, the uptake rate would be acutely sensitive to small changes in the concentration in the blood, thus forming a self-regulating system for the metabolism of beta-alanine.     

Beta-alanine and adaptation in Drosophila

Populations of Drosophila melanogaster show melanistic polymorphism. Adult melanization is inversely related to the rate of incorporation of beta-alanine into tanning cuticles. Light tan pigmentation is directly related to this incorporation. Beta-alanine induced tanning serves to protect pupae from ultraviolet light damage. Flies which do not fail to incorporate injected beta-alanine into developing cuticles, but which exhibit inhibited beta-alanine synthesis (flies homozygous for the gene ‘b’) are not only protected, as pupae, from ultraviolet damage by beta-alanine injection but also show enhanced mating success when injected as newly emerged adults. The metabolic block in this mutant appears in the pathway from orotic acid through uracil to beta-alanine.     

Responses to GABA, glycine and beta-alanine induced in Xenopus oocytes by messenger RNA from chick and rat brain

Poly (A)+ messenger RNA (mRNA) was extracted from rat and chick brains, and injected into oocytes of Xenopus laevis. This led to the expression of receptors that evoked membrane currents in response to gamma-aminobutyric acid (GABA), glycine and beta-alanine. These currents all inverted at about the chloride equilibrium potential in the oocyte, and showed a marked rectification at negative potentials. Oocytes injected with mRNA from chick optic lobe gave large responses to GABA and beta-alanine, but small responses to glycine. In contrast, one fraction of mRNA from rat cerebral cortex (obtained by sucrose density gradient centrifugation) caused oocytes to develop sensitivity to GABA, glycine and beta-alanine, but very little to GABA. The pharmacological properties of the three amino acid responses also differed. Barbiturate and benzodiazepines potentiated the responses to GABA and beta-alanine, but not to glycine. Strychnine reduced the responses to glycine and beta-alanine, but not to GABA, whereas bicuculline reduced the responses to GABA and beta-alanine, but not to glycine. We conclude that different species of mRNA code for receptors to GABA and glycine, and possibly also for separate beta-alanine receptors.     

beta-Amino acid transport across the renal brush-border membrane is coupled to both Na and Cl

Sodium-dependent beta-alanine uptake into dog renal brush-border membrane vesicles was studied. Kinetic analysis indicated a single transport system, highly specific for beta-amino acids, with Km = 35 microM at 100 mM NaCl. Sodium-dependent beta-alanine transport was markedly anion-dependent, being highest in the presence of chloride (Cl greater than Br greater than SCN greater than NO3 approximately I greater than F) and virtually nonexistent in the presence of gluconate and other nonphysiological chloride substitutes. In addition, it was observed that beta-alanine uptake could be driven against a concentration gradient by a chloride gradient. Similar results were found for sodium. Taken together, these observations provide strong evidence that beta-alanine transport across the renal brush-border membrane is coupled to both sodium and chloride. Studies of the dependence of beta-alanine flux on chloride and sodium concentrations indicated that one chloride ion and multiple sodium ions were involved in the beta-alanine transport event. beta-Alanine flux on chloride found to involve the net transfer of positive charge, consistent with these stoichiometric assignments. The hallucinogen harmaline inhibited beta-alanine uptake in a 1:1 fashion, presumably by acting at a single site on the transport molecule. The ability of harmaline to inhibit beta-alanine uptake was decreased when the chloride concentration was lowered but was unchanged when the sodium concentration was decreased. These results indicate that harmaline does not compete with sodium for a binding site on the carrier as has been suggested for other sodium-coupled transport systems, and that instead, chloride may be required for harmaline binding to the beta-alanine transporter.     

Some chemical properties of the HCl-methanol extract from the puparial cuticle of Drosophila melanogaster.

1. The HCl-methanol (HCl-MeOH) soluble fraction from the puparial cuticle of yellow, black and ebony of D. melanogaster was hydrolyzed in hydrochloric acid and examined for beta-alanine, ketocatechol, and acetic acid. 2. Between beta-alanine and ketocatechol and between beta-alanine and acetic acid, a quantitatively inverse relationship was found, respectively. The former relationship was further confirmed by the feeding experiment of beta-alanine to black. 3. Of total beta-alanine in the HCl-MeOH extract, the proportion of those having free amino group was 74.8 per cent. 4. All these results indicate that the HCl-MeOH soluble fraction of the puparial cuticle may be useful for investigating the cross-link structure of the cuticle.     

Eukaryotic beta-alanine synthases are functionally related but have a high degree of structural diversity.

beta-Alanine synthase (EC 3.5.1.6), which catalyzes the final step of pyrimidine catabolism, has only been characterized in mammals. A Saccharomyces kluyveri pyd3 mutant that is unable to grow on N-carbamyl-beta-alanine as the sole nitrogen source and exhibits diminished beta-alanine synthase activity was used to clone analogous genes from different eukaryotes. Putative PYD3 sequences from the yeast S. kluyveri, the slime mold Dictyostelium discoideum, and the fruit fly Drosophila melanogaster complemented the pyd3 defect. When the S. kluyveri PYD3 gene was expressed in S. cerevisiae, which has no pyrimidine catabolic pathway, it enabled growth on N-carbamyl-beta-alanine as the sole nitrogen source. The D. discoideum and D. melanogaster PYD3 gene products are similar to mammalian beta-alanine synthases. In contrast, the S. kluyveri protein is quite different from these and more similar to bacterial N-carbamyl amidohydrolases. All three beta-alanine synthases are to some degree related to various aspartate transcarbamylases, which catalyze the second step of the de novo pyrimidine biosynthetic pathway. PYD3 expression in yeast seems to be inducible by dihydrouracil and N-carbamyl-beta-alanine, but not by uracil. This work establishes S. kluyveri as a model organism for studying pyrimidine degradation and beta-alanine production in eukaryotes.     

Regulation of coenzyme A biosynthesis.

Coenzyme A (CoA) and acyl carrier protein are two cofactors in fatty acid metabolism, and both possess a 4'-phosphopantetheine moiety that is metabolically derived from the vitamin pantothenate. We studied the regulation of the metabolic pathway that gives rise to these two cofactors in an Escherichia coli beta-alanine auxotroph, strain SJ16. Identification and quantitation of the intracellular and extracellular beta-alanine-derived metabolites from cells grown on increasing beta-alanine concentrations were performed. The intracellular content of acyl carrier protein was relatively insensitive to beta-alanine input, whereas the CoA content increased as a function of external beta-alanine concentration, reaching a maximum at 8 microM beta-alanine. Further increase in the beta-alanine concentration led to the excretion of pantothenate into the medium. Comparing the amount of pantothenate found outside the cell to the level of intracellular metabolites demonstrates that E. coli is capable of producing 15-fold more pantoic acid than is required to maintain the intracellular CoA content. Therefore, the supply of pantoic acid is not a limiting factor in CoA biosynthesis. Wild-type cells also excreted pantothenate into the medium, showing that the beta-alanine supply is also not rate limiting in CoA biogenesis. Taken together, the results point to pantothenate kinase as the primary enzymatic step that regulates the CoA content of E. coli.     

Beta-alanine transaminase activity in black and suppressor of black mutations of Drosophila melanogaster.

An assay for beta-alanine transaminase activity in extracts of Drosophila melanogaster has been developed. By use of this assay, the levels of beta-alanine transaminase activity in several strains of flies has been examined as a function of developmental age. The black mutation shows elevated levels of activity compared to wild type, while suppressor of black strains show decreased levels compared to wild type.     

Neutral amino acid transport in Pseudomonas fluorescens

Membrane transport of beta-alanine, l-alanine, and l-proline was studied in a beta-alanine transaminaseless mutant (strain 67) of Pseudomonas fluorescens. In this mutant beta-alanine is metabolically inert, and it was therefore possible to demonstrate active transport of this substrate in the absence of intracellular catabolism. The permease which catalyzes the uptake of beta-alanine also transports l-proline and l-alanine. This common transport system was distinguished from permeases which transport only l-alanine and only l-proline by competition studies in strain 67 and by studies of transport specificity in a permeaseless mutant (strain 67/4MTR).     

Saccharomyces cerevisiae is capable of de Novo pantothenic acid biosynthesis involving a novel pathway of beta-alanine production from spermine

Pantothenic acid and beta-alanine are metabolic intermediates in coenzyme A biosynthesis. Using a functional screen in the yeast Saccharomyces cerevisiae, a putative amine oxidase, encoded by FMS1, was found to be rate-limiting for beta-alanine and pantothenic acid biosynthesis. Overexpression of FMS1 caused excess pantothenic acid to be excreted into the medium, whereas deletion mutants required beta-alanine or pantothenic acid for growth. Furthermore, yeast genes ECM31 and YIL145c, which both have structural homology to genes of the bacterial pantothenic acid pathway, were also required for pantothenic acid biosynthesis. The homology of FMS1 to FAD-containing amine oxidases and its role in beta-alanine biosynthesis suggested that its substrates are polyamines. Indeed, we found that all the enzymes of the polyamine pathway in yeast are necessary for beta-alanine biosynthesis; spe1Delta, spe2Delta, spe3Delta, and spe4Delta are all beta-alanine auxotrophs. Thus, contrary to previous reports, yeast is naturally capable of pantothenic acid biosynthesis, and the beta-alanine is derived from methionine via a pathway involving spermine. These findings should facilitate the identification of further enzymes and biochemical pathways involved in polyamine degradation and pantothenic acid biosynthesis in S. cerevisiae and raise questions about these pathways in other organisms.     

Beta-alanine protection against hypoxic liver injury in the rat

Liver hypoxia still represents an important cause of liver injury during shock and liver transplantation. We have investigated the protective effects of beta-alanine against hypoxic injury using isolated perfused rat livers and isolated rat hepatocyte suspensions. Perfusion with hypoxic Krebs-Henseleit buffer increased liver weight and caused a progressive release of lactate dehydrogenase (LDH) in the effluent perfusate. The addition of 5 mmol/l beta-alanine to the perfusion buffer completely prevented both weight increase and LDH leakage. These findings were confirmed by histological examinations showing that beta-alanine blocked the staining by trypan blue of either liver parenchymal and sinusoidal cells. Studies performed in isolated hepatocytes revealed that beta-alanine exerted its protective effects by interfering with Na+ accumulation induced by hypoxia. The addition of gamma-amino-butyric acid, which interfered with beta-alanine uptake by the hepatocytes or of Na+/H+ ionophore monensin, reverted beta-alanine protection in either hepatocyte suspensions or isolated perfused livers. We also observed that liver receiving beta-alanine were also protected against LDH leakage and weight increase caused by the perfusion with an hyposmotic (205 mosm) hypoxic buffer obtained by decreasing NaCl content from 118 to 60 mmol/l. This latter effect was not reverted by blocking K+ efflux from hepatocyte with BaCl(2) (1mmol/l). Altogether these results indicated that beta-alanine protected against hypoxic liver injury by preventing Na+ overload and by increasing liver resistance to osmotic stress consequent to the impairment of ion homeostasis during hypoxia.     

Analysis of pyrimidine catabolism in Drosophila melanogaster using epistatic interactions with mutations of pyrimidine biosynthesis and beta-alanine metabolism

The biochemical pathway for pyrimidine catabolism links the pathways for pyrimidine biosynthesis and salvage with beta-alanine metabolism, providing an array of epistatic interactions with which to analyze mutations of these pathways. Loss-of-function mutations have been identified and characterized for each of the enzymes for pyrimidine catabolism: dihydropyrimidine dehydrogenase (DPD), su(r) mutants; dihydropyrimidinase (DHP), CRMP mutants; beta-alanine synthase (betaAS), pyd3 mutants. For all three genes, mutants are viable and fertile and manifest no obvious phenotypes, aside from a variety of epistatic interactions. Mutations of all three genes disrupt suppression by the rudimentary gain-of-function mutation (r(Su(b))) of the dark cuticle phenotype of black mutants in which beta-alanine pools are diminished; these results confirm that pyrimidines are the major source of beta-alanine in cuticle pigmentation. The truncated wing phenotype of rudimentary mutants is suppressed completely by su(r) mutations and partially by CRMP mutations; however, no suppression is exhibited by pyd3 mutations. Similarly, su(r) mutants are hypersensitive to dietary 5-fluorouracil, CRMP mutants are less sensitive, and pyd3 mutants exhibit wild-type sensitivity. These results are discussed in the context of similar consequences of 5-fluoropyrimidine toxicity and pyrimidine catabolism mutations in humans.     

Reverse structure of carnosine-induced sedative and hypnotic effects in the chick under acute stress

In the central nervous system, beta-alanine is thought to act as an inhibitory neurotransmitter, but the role or precise mechanism of beta-alanine in the brain has not been clearly defined. beta-Alanine is found in high levels in the chicken brain as a component of the dipeptides carnosine (beta-alanyl-L-histidine) and anserine, or as a free amino acid. We focused on the position of beta-alanine, i.e., at the carboxyl terminus. In Experiment 1, the central effects of glycyl-beta-alanine, L-histidyl-beta-alanine and L-valyl-beta-alanine were compared with a saline control in chicks. L-Histidyl-beta-alanine significantly induced sedative and hypnotic effects. In Experiment 2, the effects of carnosine, its reverse (L-histidyl-beta-alanine), and their combination were investigated. Central carnosine-induced hyperactivity while reverse carnosine-induced hypoactivity, and the behaviors were intermediate following the combination of the two peptides. Finally, the central effect of reverse carnosine was compared with beta-alanine alone and L-seryl-beta-alanine in Experiment 3. Reverse carnosine showed similar effects to beta-alanine. In conclusion, L-histidyl-beta-alanine not only has the reverse structure of carnosine, but also reverse function. Thus, we propose to name reverse carnosine (L-histidyl-beta-alanine) rev-carnosine.     

Amidohydrolases of the reductive pyrimidine catabolic pathway purification, characterization, structure, reaction mechanisms and enzyme deficiency

In the reductive pyrimidine catabolic pathway uracil and thymine are converted to beta-alanine and beta-aminoisobutyrate. The amidohydrolases of this pathway are responsible for both the ring opening of dihydrouracil and dihydrothymine (dihydropyrimidine amidohydrolase) and the hydrolysis of N-carbamyl-beta-alanine and N-carbamyl-beta-aminoisobutyrate (beta-alanine synthase). The review summarizes what is known about the properties, kinetic parameters, three-dimensional structures and reaction mechanisms of these proteins. The two amidohydrolases of the reductive pyrimidine catabolic pathway have unrelated folds, with dihydropyrimidine amidohydrolase belonging to the amidohydrolase superfamily while the beta-alanine synthase from higher eukaryotes belongs to the nitrilase superfamily. beta-Alanine synthase from Saccharomyces kluyveri is an exception to the rule and belongs to the Acyl/M20 family.     

Specialization of function among aldehyde dehydrogenases: the ALD2 and ALD3 genes are required for beta-alanine biosynthesis in Saccharomyces cerevisiae

The amino acid beta-alanine is an intermediate in pantothenic acid (vitamin B(5)) and coenzyme A (CoA) biosynthesis. In contrast to bacteria, yeast derive the beta-alanine required for pantothenic acid production via polyamine metabolism, mediated by the four SPE genes and by the FAD-dependent amine oxidase encoded by FMS1. Because amine oxidases generally produce aldehyde derivatives of amine compounds, we propose that an additional aldehyde-dehydrogenase-mediated step is required to make beta-alanine from the precursor aldehyde, 3-aminopropanal. This study presents evidence that the closely related aldehyde dehydrogenase genes ALD2 and ALD3 are required for pantothenic acid biosynthesis via conversion of 3-aminopropanal to beta-alanine in vivo. While deletion of the nuclear gene encoding the unrelated mitochondrial Ald5p resulted in an enhanced requirement for pantothenic acid pathway metabolites, we found no evidence to indicate that the Ald5p functions directly in the conversion of 3-aminopropanal to beta-alanine. Thus, in Saccharomyces cerevisiae, ALD2 and ALD3 are specialized for beta-alanine biosynthesis and are consequently involved in the cellular biosynthesis of coenzyme A.     

Carnosine Synthesis in Olfactory Tissue During Ontogeny: Effect of Exogenous β-Alanine

Carnosine has now been demonstrated by chemical analysis to be present in rat olfactory mucosa on day 16 of gestation. The tissue content of this dipeptide then increases progressively during fetal and postnatal life. Radioactive carnosine can be isolated from cultured embryonic rat olfactory mucosa incubated with [14C]beta-alanine as early as 13-14 days of gestation. The amount of incorporation also increases progressively with the initial age of the explant and with time in culture indicating in vitro maturation of the carnosine synthesis capability of olfactory tissue. To test whether the level of beta-alanine was limiting the synthesis of carnosine, we evaluated the effect of elevated beta-alanine levels on tissue carnosine content. Exogenous beta-alanine caused an increase in the tissue content of carnosine at several ages in vivo and in vitro. In adult animals this increase was observed in olfactory bulb, olfactory mucosa, and skeletal muscle. However, there was no associated alteration in carnosine synthetase activity. In addition, the different half-lives of carnosine in olfactory tissue and muscle seemed unaltered, arguing against any effect on degradative enzymes. Thus, tissue carnosine levels are regulated, at least in part, by substrate availability. The early appearance of carnosine synthetic capacity during prenatal development indicates that this enzyme activity should be a valuable aid in studying early events in olfactory neuron maturation.     

The identification of the N tau-methyl histidine-containing dipeptide, balenine, in muscle extracts from various mammals and the chicken

The occurrence of the dipeptide, balenine (beta-alanyl-N tau-methyl histidine), has been identified by comparative chromatography in extracts of muscles from 9 species of mammal, including man, and the chicken. The identity of the dipeptide from 6 mammalian species and chicken was confirmed by preparative isolation prior to determination of the amino acid composition and N-terminal residue. In all cases, the dipeptide contained equimolar amounts of beta-alanine and N tau-methyl histidine with beta-alanine as the N-terminus. The concentration of the dipeptide varied dramatically between species, being just detectable in the muscle of man and rat while present at concentrations of up to 14 mumol/g wet muscle in adult pigs. It is proposed that balenine, like carnosine and anserine, should be regarded as a normal constituent of muscle.