Metabolism of polyamines in mouse neuroblastoma cells in culture: formation of GABA and putreanine.

—Polyamine metabolism of mouse neuroblastoma cells grown in culture was studied with special reference to the synthesis of GABA from putrescine and putreanine from spermidine. This study shows that neuroblastoma cells in the presence of a complete culture medium containing calf serum readily metabolized [¹⁴C]putrescine to GABA; the rate of synthesis is similar to the rate of synthesis of spermidine from putrescine. In the absence of serum the conversion of putrescine to GABA is minimal. In the presence of serum GABA formation is completely inhibited by the diamine oxidase inhibitor aminoguanidine. GABA synthesis does not occur in the absence of cells. The GABA synthesized is not readily metabolized to succinate or homocarnosine. Mouse neuroblastoma cells metabolized [¹⁴C]ornithine to putrescine, GABA, and spermidine. Spermidine was metabolized to putrescine, putreanine and spermine.     

Formation of gamma-aminobutyric acid from glutamate and putrescine in rat hypothalamic and hippocampal synaptosomes and regulation of these processes by glucocorticoids]

It has been shown that single or multiple hydrocortisone and ACTH administrations to intact rats increased GABA content and its synthesis from glutamate and putrescine in synaptosomes of hypothalamus. The letter content was increased by single hormonal administration while multiple hormonal administration and adrenalectomy decreased it. Ornithine decarboxylase activity was increased by single hydrocortisone administration to intact animals, following adrenalectomy, and it was decreased by single hormonal administration to adrenalectomized rats. GABA synthesis in synaptosomes of hippocampus from putrescine was increased by single hydrocortisone and multiple hormonal administrations. GABA content was increased by multiple administration of both hormones and was decreased by adrenalectomy. Putrescine level was decreased by multiple hydrocortisone administration to intact and single administration to adrenalectomized rats; ornithine decarboxylase activity was decreased by multiple administration of both hormones.     

Polyamines appear to be second messengers in mediating Ca2+ fluxes and neurotransmitter release in potassium-depolarized synaptosomes

High potassium (50 mM) depolarization induces a rapid (less than 15 sec) increase in the levels of the polyamines putrescine, spermidine and spermine and their rate-regulating synthetic enzyme ornithine decarboxylase in synaptosomes from rat cerebral cortex. The ornithine decarboxylase inhibitor alpha-difluoromethylornithine blocked the K+-stimulated increase in enzyme activity and polyamines and also suppressed the increase in 45Ca2+ influx and efflux and the Ca2+-dependent release of GABA and norepinephrine. Added putrescine attenuated or negated the effects of alpha-difluoromethylornithine. These results suggest that enhanced polyamine synthesis is required for potassium depolarized stimulation of synaptic function.     

Metabolic routes of GABA formation in chick embryo brain

Sobue and Nakajima (1978) reported that GABA formation from putrescine is significant in chick embryo brain between days 6 and 8 of incubation. They attributed an important functional role to the putrescine-derived GABA. We found that depletion of putrescine and spermidine in chick embryos by inhibition of ornithine decarboxylase activity did not decrease the in vivo rate of GABA formation, showing that putrescine is, from a quantitative point of view, a negligible source for GABA in chick embryo brain. The changes of brain GABA levels obtained after administration of glutamate decarboxylase inhibitors and in vitro determinations of glutamate decarboxylase activity were compatible with the assumption that GABA is mainly formed by decarboxylation of l-glutamate, even during early brain development. Participation of the NAD⁺-dependent, aerobic transformation of glutamate into GABA (Seiler and Wagner, 1976) in the overall GABA production of chick embryo brain could, however, not be excluded.     

Association of putrescine,spermidine, spermine,and GABA with structural elements of brain cells

The present experiments are the first survey of the association of endogenous and exogenous putrescine, spermidine, and spermine with subcellular structures of rat brain cortex. The differences of distribution in subfractions obtained from salt-free and salt-containing density gradients were studied, with the following results: (1) In contrast with liver preparation, putrescine and the polyamines spermidine and spermine are not distributed in parallel with RNA. (2) In salt-containing media, putrescine and the polyamines were preferentially associated with synaptosomes and with synaptosomal membranes. Significant association with myelin constituents was observed only in salt-free media. (3) Exogenous putrescine and the polyamines were less firmly attached to synaptosomes and to synaptosomal membrane fractions than the endogenous amines. There is good evidence for similar subcellular localizations of putrescine and GABA. Putrescine seems to be entrapped in the nerve endings. (4) Uptake studies with crude mitochondria under conditions of high-affinity uptake showed no temperature-sensitive component of polyamine accumulation in synaptosomes, in contrast with GABA, monoacetylputrescine, and ornithine. (5) Polyamines bound to myelin constituents or mitochondria could be displaced by a 200-fold concentration of nonradioactive amines; this was not the case with polyamines bound to synaptosomes. Mg²⁺ did not effectively compete with spermine for binding sites at synaptic regions. (6) Electrical stimulation and stimulation by mono- and bivalent cations did not change the concentrations of the polyamines and GABA in guinea pig cortex. (7) There is no evidence for a neurotransmitter role of putrescine, spermidine, or spermine, although these compounds might function as modulators of neurotransmission.     

Studies on the release of exogenous and endogenous GABA and glutamate from rat brain synaptosomes

The aim of the present study was to determine whether exogenous radioactive GABA and glutamate previously taken up by rat brain synaptosomes are released preferentially with respect to the endogenous unlabeled amino acids. Preferential release was monitored by comparing the specific radioactivity of the amino acids released to that present in synaptosomes at the beginning and at the end of the release period. The GABA released spontaneously or by depolarizing the synaptosomes with high K⁺ in the presence of Ca²⁺ had the same specific radio-activity as that present in synaptosomes before or after superfusion. Depolarization with veratridine or superfusion with OH-GABA caused a moderate increase (15–20%) in the specific radioactivity of the GABA released and a corresponding slight decrease in that of superfused synaptosomes. In conditions causing a supraadditive release of exogenous and endogenous GABA (see ref. 13), the specific radioactivity of the GABA released was increased 20–30%. The GABA with higher-than-average specific radioactivity is probably representative of the cytoplasmic pool of this amino acid. The glutamate released spontaneously had a specific radioactivity lower than that present in synaptosomes at the start of superfusion, and also the specific radioactivity in superfused synaptosomes was lower than at the start of superfusion. The glutamate released by aspartate (by heteroexchange), by veratridine, or by high K⁺ had a specific radioactivity higher than that of the amino acid released spontaneously, similar to that present in synaptosomes at the start of superfusion, and higher than that found in superfused synaptosomes. These findings suggest that exogenous radioactive glutamate is released preferentially with respect to the endogenous amino acid and to the glutamate synthesized from glucose during the superfusion period.     

METABOLISM OF GLUCOSE AND GLUTAMATE BY SYNAPTOSOMES FROM MAMMALIAN CEREBRAL CORTEX

—(1) Synaptosomes incubated in high sodium, low potassium media showed high linear respiration in the presence of glucose which was converted into lactate, aspartate, glutamate, glutamine, alanine and GABA during 1 hr incubation periods. (2) Total conversion of glucose into most of these substrates over the incubation period was similar in synaptosomes and cortex slices. Half the lactate and only a small fraction of the glutamine made by slices was formed by synaptosomes. (3) Pool sizes of amino acids in cortex slices after incubation with glucose were, in general, higher than in synaptosomes, glutamate and glutamine being four-fold higher in slices. (4) Most of the amino acids made from glucose by synaptosomes were contained within their structure and not lost to the medium. (5) Glutamate was actively metabolized by synaptosomes to aspartate, glutamine, alanine and GABA. The specific radioactivities of the amino acids (except glutamine) after 1 hr incubation, approached that of the glutamate. (6) Pyridoxal phosphate added to the incubation medium increased GABA production from glutamate but not from glucose.     

Transgenic manipulation of a single polyamine in poplar cells affects the accumulation of all amino acids

The polyamine metabolic pathway is intricately connected to metabolism of several amino acids. While ornithine and arginine are direct precursors of putrescine, they themselves are synthesized from glutamate in multiple steps involving several enzymes. Additionally, glutamate is an amino group donor for several other amino acids and acts as a substrate for biosynthesis of proline and γ-aminobutyric acid, metabolites that play important roles in plant development and stress response. Suspension cultures of poplar (Populus nigra × maximowiczii), transformed with a constitutively expressing mouse ornithine decarboxylase gene, were used to study the effect of up-regulation of putrescine biosynthesis (and concomitantly its enhanced catabolism) on cellular contents of various protein and non-protein amino acids. It was observed that up-regulation of putrescine metabolism affected the steady state concentrations of most amino acids in the cells. While there was a decrease in the cellular contents of glutamine, glutamate, ornithine, arginine, histidine, serine, glycine, cysteine, phenylalanine, tryptophan, aspartate, lysine, leucine and methionine, an increase was seen in the contents of alanine, threonine, valine, isoleucine and γ-aminobutyric acid. An overall increase in percent cellular nitrogen and carbon content was also observed in high putrescine metabolizing cells compared to control cells. It is concluded that genetic manipulation of putrescine biosynthesis affecting ornithine consumption caused a major change in the entire ornithine biosynthetic pathway and had pleiotropic effects on other amino acids and total cellular carbon and nitrogen, as well. We suggest that ornithine plays a key role in regulating this pathway.     

Uptake of GABA and putrescine by UGA4 on the vacuolar membrane in Saccharomyces cerevisiae

The product of the UGA4 gene in Saccharomyces cerevisiae, which catalyzes the transport of 4-aminobutyric acid (GABA), also catalyzed the transport of putrescine. The Km values for GABA and putrescine were 0.11 and 0.69 mM, respectively. The UGA4 protein was located on the vacuolar membrane as determined by the effects of bafilomycin A1 and by indirect immunofluorescence microscopy. Uptake of both GABA and putrescine was inhibited by spermidine and spermine, although these polyamines are not substrates of UGA4. The UGA4 mRNA was induced by exposure to GABA, but not putrescine over 12h. The growth of an ornithine decarboxylase-deficient strain was enhanced by putrescine, and both putrescine and spermidine contents increased, when the cells were expressing UGA4. The results suggest that a substantial conversion of putrescine to spermidine occurs in the cytoplasm even though UGA4 transporter exists on vacuolar membranes.     

A New Synaptosomal Biosynthetic Pathway of Glutamate and GABA from Ornithine and Its Negative Feedback Inhibition by GABA

In sonicates of mouse brain synaptosomes, we demonstrated that gamma-aminobutyric acid (GABA) can be formed when L-ornithine (Orn) through L-glutamic acid (Glu), but not through putrescine (Put). Incubation of these sonicates with [3H]ORN yielded not only [3H]Glu and [3H]L-proline (Pro) but also produced [3H]GABA from the [3H]Glu. Formation of each of these three major amino acids from [3H]Orn was strongly inhibited by the addition of GABA (1-5 mM). The likely enzymatic site of this negative feedback inhibition by GABA appeared to be ornithine delta-aminotransferase (OAT). A radiometric procedure was employed to study the effects of the three amino acids cited above and of others found in the free form in brain on the activity of a 30-fold-purified OAT from rat brain. Enzyme activity was measured in the presence of low concentrations of Orn, such as might occur in vivo. OAT was inhibited by GABA to a considerably greater extent than by Glu, L-glutamine, or Put; no inhibition was found with Pro, glycine, aspartarte, taurine, or beta-alanine. The inhibition of GABA was competitive with Orn. These results clearly show that one of the molecular mechanisms underlying the negative feedback inhibition of synaptosomal GABA biosynthesis from Orn is a competitive inhibition by GABA of the brain OAT activity that is responsible for the formation of L-glutamic-gamma-semialdehyde in equilibrium with L-delta 1-pyrroline-5-carboxylic acid from Orn. Thus, the results suggest that GABA may play an important role in restricting the metabolic flow from Orn to Glu and thence to GABA. It is confirmed that L-canaline (delta-aminooxy-L-alpha-aminobutyric acid) is a potent and specific inhibitor of brain OAT whereas much weaker inhibition was observed with two other carbonyl-trapping agents, aminooxyacetic acid and hydrazine.     

Metabolic Compartmentation in Cortical Synaptosomes: Influence of Glucose and Preferential Incorporation of Endogenous Glutamate into GABA

Metabolism of glutamine was determined under a variety of conditions to study compartmentation in cortical synaptosomes. The combined intracellular and extracellular amounts of [U-¹³C]GABA, [U-¹³C]glutamate and [U-¹³C]glutamine were the same in synaptosomes incubated with [U-¹³C]glutamine in the presence and absence of glucose. However, the concentration of these amino acids was decreased in the latter group, demonstrating the requirement for glucose to maintain the size of neurotransmitter pools. In hypoglycemic synaptosomes more [U-¹³C]glutamine was converted to [U-¹³C]aspartate, and less glutamate was re-synthesized from the tricarboxylic acid (TCA) cycle, suggesting use of the partial TCA cycle from -ketoglutarate to oxaloacetate for energy. Compartmentation was studied in synaptosomes incubated with glucose plus labeled and unlabeled glutamine and glutamate. Incubation with [U-¹³C]glutamine plus unlabeled glutamate gave rise to [U-¹³C]GABA but not labeled aspartate; however, incubation with [U-¹³C]glutamate plus unlabeled glutamine gave rise to [U-¹³C]aspartate, but not labeled GABA. Thus the endogenous glutamate formed via glutaminase in synaptic terminals is preferentially used for GABA synthesis, and is metabolized differently than glutamate taken up from the extracellular milieu.     

Tissue Distribution, Metabolism, Anticonvulsant Efficacy, and Effect on Brain Amino Acid Levels of the Glia-Selective γ-Aminobutyric Acid Transport Inhibitor 4,5,6,7-Tetrahydroisoxazolo[4,5-c]pyridin-3-ol in Mice and Chicks

Using tritium-labelled 4,5,6,7-tetrahydroisoxazolo[4,5-c]pyridin-3-ol (THPO) its tissue distribution and metabolism were investigated in adult mice and 4-day-old chicks after systemic administration of the drug. It was found not to be significantly metabolized in the brain since metabolites of THPO corresponding to only approximately 8% of the parent compound could be detected 30 min after administration of the drug intramuscularly in mice. In the liver, however, THPO was found to be metabolized to a considerable extent. In chicks THPO metabolites were found in the brain but they accounted for less than 35% of the radioactivity. The brain concentration of THPO in mice and chicks corresponded to respectively 10 and 50% of the dose injected intramuscularly and the tissue level was essentially constant for at least 3 h after injection. Following systemic administration of THPO to mice and chicks the contents of aspartate, glutamate, glutamine, and gamma-aminobutyric acid (GABA) in whole brain and in synaptosomes was determined. It was found that only GABA contents were affected being increased in synaptosomes from mice and decreased in whole brain in chicks. Doses of THPO, which in chicks but not in mice led to brain levels that were sufficient to inhibit glial GABA uptake, were found to protect chicks but not mice against isonicotinic acid hydrazide-induced seizures. The findings are compatible with the notion that THPO exerts its anticonvulsant activity by inhibition of astrocytic GABA uptake.     

GABA and its relationship to putrescine metabolism in the rat brain and pancreas

The possibility that GABA may have its origin in putrescine was investigated in the rat pancreas, relative to the brain. These studies show that radioactive putrescine is converted to GABA at a similar rate in both the pancreas and brain, but that putrescine accounts for only a small fraction of the GABA found in these organs. Inhibitors of diamine and monoamine oxidases do not significantly change the GABA level in the pancreas. In contrast to the brain, where putrescine is catabolized to GABA via monoamine oxidase, the primary catabolic pathway of putrescine to GABA in the pancreas is via diamine oxidase. In vivo studies show that AOAA inhibits GABA-T activity to the same degree in the pancreas as in the brain, elevating GABA levels more than 2-fold in 4 h. GABA is metabolized more rapidly in the brain than the pancreas. Turnover times of GABA in the pancreas and brain are 1.9 and 1.0 h, respectively. The slower turnover of GABA in the pancreas than in the brain may relate to a neuromodulatory role for GABA, similar to that for neuropeptides. Developmental studies in the postnatal pancreas suggest a role for GABA in the maturation of insulin secretion.     

Entrapping of impermeant probes of different size into nonpermeabilized synaptosomes as a method to study presynaptic mechanisms

Small molecules present during brain tissue homogenization are known to be entrapped within subsequently isolated synaptosomes. We have revisited this technique in view of its systematic utilization to incorporate into nerve endings impermeant probes of large size. Rat neocortical synaptosomes were prepared in the absence or in the presence of each of the following compounds: 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid (BAPTA), tetanus toxin (TeTx) or its light chain (TeTx-LC), pertussis toxin (PTx), anti-syntaxin, or anti-SNAP25 monoclonal antibodies. Release of endogenous GABA and glutamate was then evoked by high K+ depolarization. GABA and glutamate overflows were inhibited by entrapped BAPTA and in synaptosomes prepared by homogenization in the presence of varying concentrations of TeTx or TeTx-LC. When synaptobrevin cleavage in synaptosomes entrapped with TeTx was monitored by sodium dodecyl sulfate-polyacrylamide gel electrophoresis followed by western blotting, the extent of proteolysis was found to correspond quantitatively to that of release inhibition. GABA and glutamate overflows were increased by entrapped PTx; moreover, (-)-baclofen inhibited amino acid overflow more potently in standard than in PTx-containing synaptosomes. The overflows of GABA and glutamate were similarly decreased following incorporation of anti-syntaxin or anti-SNAP25 antibodies. Synaptosomal entrapping may be routinely used to internalize membrane-impermeant agents of different size in studies of presynaptic mechanisms.     

Hormonal control of metabolism of gamma-aminobutyric acid in the rat hypothalamus and hippocampus

It has been established that hydrocortisone administration increased the amount of total, free, bound and synaptosomal GABA in the hypothalamus, glutamate decarboxylase activity in the homogenate and synaptosomes and time of the mediator turnover. ACTH administration increased the GABA content and glutamate decarboxylase activity in synaptosomes. The total amino acid content and time of its turnover got higher only with single hormone administration. In the hippocamp hydrocortisone administration increased the total and free GABA contents, its turnover time, glutamate decarboxylase activity in the homogenate and decreased GABA-aminotransferase activity in the homogenate and synaptosomes. The GABA level in synaptosomes grew only with multiple hormone administration. Single administration of ACTH decreased the total GABA content, glutamate decarboxylase activity in the homogenate, while its multiple administration increased the GABA level in synaptosomes followed by a decrease of GABA-aminotransferase activity in the homogenate and synaptosomes. The GABA turnover time fell with single hormone administration and grew with the multiple one. Adrenalectomy induced no changes in the GABA content and activity of its metabolism enzymes in the hypothalamus, however the bound GABA level decreased, while the turnover time increased. In the hippocamp adrenalectomy decreased total, free and synaptosomal GABA contents, glutamate decarboxylase activity in a homogenate and turnover time. Subsequent hydrocortisone administration only partly normalized the revealed changes of the GABA metabolism in the brain structures under adrenalectomy.     

A Sensitive Radiometric Assay for Ornithine Aminotransferase: Regional and Subcellular Distributions in Rat Brain

Abstract: A radiometric assay for ornithine aminotransferase was developed using [1-¹⁴C]α-ketoglutarate as the labeled substrate and glutamate decarboxylation as a linking step. This assay gives near total measurement of ornithine aminotransferase activities that are, respectively, about 1.5 and 10 times larger than those obtained by the spectrophotometric assay and the radiometric assay using [1-¹⁴C]ornithine. It is also the most sensitive of the three assay procedures.
Consistent with previous reports, brain ornithine aminotransferase was found to be present predominantly in synaptosomes. Regional distribution of the enzyme correlated with that of the high-affinity uptake of glutamate, but not with the distribution of glutamate decarboxylase. Ornithine aminotransferase may be responsible for the synthesis of glutamate in glutamatergic neurons but it is clearly not localized exclusively in such neurons.     

Cortical modulation of cholinergic neurons in the striatum

Previous reports suggest the existence of a cortico-striatal pathway which might use glutamate as the transmitter. In the present study, the possible influence of this pathway on striatal cholinergic neurons was investigated. Two weeks following surgical destruction of the cerebral cortex, the high affinity uptake of glutamate and choline into striatal synaptosomes was significantly reduced whereas GABA uptake was unaffected. In acute experiments (1 hour following decortication), only choline uptake was significantly reduced while the uptake of glutamate and GABA were not altered. Acute injection (2 minutes) of kainic acid into the striatum, 1 hour after decortication, reversed the effect of the decortication on choline uptake, perhaps by simulating an excitatory input to the striatum which was presumably removed by the cortical ablation. These observations are consistent with the existence of a cortical input (perhaps glutamatergic) to the striatum and suggest that striatal cholinergic neurons can be influenced by this cortico-striatal pathway.     

Insulin regulation of RNA synthesis

During periods of nitrogen exportation from the cell, mitochondrial carbamoyl phosphate is synthesized, thus initiating the urea cycle. During times of nitrogen conservation by the liver cell, carbamoyl phosphate is synthesized in the cytosol of the cell, whereupon the de novo pyrimidine synthesis pathway is initiated. The de novo pathway provides pyrimidines for increased ribonucleic acid synthesis. Formerly, it was believed that these two pathways functioned irrespective of one another. However, recent experimental evidence indicates that, when excess ammonia is present, mitochondrial carbamoyl phosphate passes from the mitochondria into the cell cytosol, where it is metabolized by the de novo pyrimidine synthesis pathway. When ornithine and excess ammonia are both present, mitochondrial carbamoyl phosphate no longer passes from the mitochondria into the cytosol to be metabolized by the de nova pathway. Thus the metabolic fate of mitochondrial carbamoyl phosphate, and that of excess nitrogen, is determined by the presence or absence of ornithine. In turn, this key molecule is the substrate for the cytoplasmic enzyme ornithine decarboxylase. When ornithine decarboxylase is stimulated by insulin, ornithine is metabolized to putrescine. The activated ornithine decarboxylase combines with ribonucleic acid polymerase, activating the later enzyme. When ornithine is acted upon by ornithine decarboxylase, it is no longer available for the perpetuation of the urea cycle and mitochondrial carbamoyl phosphate levels rise until the carbamoyl phosphate passes into the cytosol to be metabolized by the de novo pathway. Increased amounts of pyrimidines are available for the activated ribonucleic acid polymerase. Therefore insulin, through its stimulation of ornithine decarboxylase, achieves cellular nitrogen retention by regulating nitrogen incorporation into newly synthesized ribonucleic acid.     

Glutamate metabolism in the brain of young rats exposed to organic and inorganic lead

The synthesis of glutamate and its conversion to glutamine and GABA were studied using labelled glucose in cerebral cortex, cerebellum and brainstem of rats intoxicated acutely with tetraethyl lead and chronically with lead acetate. To assess the interconversion and the synaptosomal accumulation of these amino acids, the labelling of glutamate, glutamine and GABA were measured in whole tissue and synaptosomes after giving labelled glutamate. The radioactive carbon dioxide production from labelled glutamate by brain slices was measured to evaluate the oxidation of glutamate. The tissue levels of glutamate, glutamine and GABA and the activity of glutamate decarboxylase were also measured in both conditions.In inorganic lead toxicity, even though the glutamate pool size was reduced, the glutamate-glutamine cycling between synaptosomes and astrocytes was increased. The oxidation of glutamate and the glutamate-GABA cycling were reduced. These findings suggest that brain tries to maintain the endogenous glutamate levels by decreasing the oxidation of glutamate and increasing the uptake systems and the cycling through glutamine in inorganic lead toxicity. In organic lead toxicity, the glutamate pool as well as glutamate turnover was reduced markedly resulting in complete distortion of glutamate metabolism.