Distribution and tissue specificity of 4-aminobutyrate-2-oxoglutarate aminotransferase

A rapid and specific method for assaying 4-aminobutyrate-2-oxoglutarate aminotransferase was developed. The method was based on the selectivity of ion exchange resin and the speed of vacuum filtration. With this new method, the aminotransferase activity in various tissues has been determined as follows: brain, 10.2; spinal cord, 11.8; liver, 5.7; kidney, 4.6; heart, 0.5; lung, 0.4 nmol glutamate formed/min/mg. No activity could be detected in muscle preparations. When the aminotransferases were tested with the antibody, against the purified 4-aminobutyrate aminotransferase from brain, no difference could be detected among brain, spinal cord, and kidney preparations as judged from the results of immunodiffusion, inhibition of enzyme activity by antibody, and microcomplement fixation. It is concluded that 4-aminobutyrate aminotransferases from various tissues of the mouse are probably identical or closely related.This work was supported in part by Grant No. NS 13224 and P01 NS 12116 from the National Institutes of Health, U.S.A. and Grant from Huntington's Chorea Foundation.All correspondence should be addressed to Dr. Wu.     

THE DISTRIBUTION OF GLUTAMATE DECARBOXYLASE IN RAT TISSUES; ISOTOPIC VS FLUORIMETRIC ASSAYS

—The activity of glutamate decarboxylase (GAD, EC 4.1.1.15) in normal and neoplastic rat tissues was determined by two assay methods, one based on the production of ¹⁴CO₂ from [¹⁴C]glutamic acid and the other on the fluorimetric measurement of γ-aminobutyric acid (GABA) formation. Activities obtained with the isotopic assay were high in every tissue (ranging from over 800 in liver and brain to 107nmol CO₂/min/g in lung). They were drastically diminished by Triton X-100, by an oxygen-free atmosphere or by the mitochondrial electron transport inhibitors, rotenone and antimycin A. Activities measured fluorimetrically were significant in only a few tissues and were stimulated by Triton (e.g. from 299 to 569 nmol GABA/min/g brain) but were unaffected by rotenone. For several tissues after Triton treatment the fluorimetric and isotopic assays (in air) gave the same results (i.e. the two end products, CO₂ and GABA were in stoichiometric agreement); however, the fluorimetric assay remains the more reliable measure of GAD activity since Triton may not inhibit completely the non-GAD dependent decarboxylation of glutamate in all types of tissue preparations. The hepatic, renal and mammary tumours tested were devoid of GAD; among non-neural normal tissues, kidney, liver and, possibly, adrenal gland contained significant GAD activity. In kidney and liver the activity was 15 and 10 per cent of that in brain.     

Species specificities of l-glutamic acid decarboxylase: Immunochemical comparisons

The relationship of catfish brain l-glutamic acid decarboxylase (GAD) with those from other species were examined by comparing the extent of their interactions with antibodies against catfish brain GAD. Several immunochemical methods, such as immunodiffusion, inhibition of enzyme activity and microcomplement fixation tests were employed for these studies. Antibodies against GAD from catfish brain were observed to cross-react with the enzymes from goldfish, frog, chick and turtle. Rabbit and bovine GAD did not cross-react with these antibodies. In the presence of the antibodies, enzymes from goldfish, frog. Drosophila, chick and crayfish were inhibited 27, 46, 32, 38 and 57% respectively. Enzymes from all the other species examined were not affected at all. Microcomplement fixation tests showed that goldfish, frog and chick GAD were quite similar in immunoreactivities. These immunochemical studies demonstrated that GAD from lower vertebrates such as chick, goldfish and frog and some invertebrates such as Drosophila and crayfish are closely related to catfish GAD. In contrast, mammalian GAD shows little or no cross-reactivity with antibodies against catfish GAD.     

Origin of hydrogen required for fatty acid synthesis in isolated rat adipocytes.

Beef liver and beef spinal cord d-glycerate dehydrogenases have been shown to be extremely similar. No differences between the two enzymes could be shown by polyacrylamide electrophoresis, sodium dodecyl sulfate polyacrylamide electrophoresis, immunodiffusion, immunoelectrophoresis, or their response to certain inhibitors. Differences could be obtained, however, between the beef spinal cord enzyme and the hog spinal cord enzyme by immunodiffusion and immunoelectrophoresis.Only by the very sensitive technique of microcomplement fixation could a small but significant difference be shown between the beef liver and beef spinal cord enzymes. Like the beef liver and hog spinal cord enzymes, the beef spinal cord enzyme was not inhibited by high concentrations of serine or glycine. The enzyme was inhibited however by low concentrations of phosphohydroxypyruvate and by other phosphorylated compounds.     

REGIONAL DISTRIBUTION AND PROPERTIES OF THE GLYCINE CLEAVAGE SYSTEM WITHIN THE CENTRAL NERVOUS SYSTEM OF THE RAT: EVIDENCE FOR AN ENDOGENOUS INHIBITOR DURING IN VITRO ASSAY

—The activity of the glycine cleavage system (GCS) was determined in homogenates from five specific regions of the rat CNS (telencephalon, midbrain, cerebellum, medulla-pons, and spinal cord). An inverse trend was noted between the glycine content and the specific activity of the GCS in the regions. A 25-fold range in the enzyme activities was found between the telencephalon (highest) and the spinal cord (lowest). The properties of the GCS activity in CNS homogenates agreed with those properties previously described for this system in partially purified preparations of liver and brain mitochondria (Kikuchi , 1973; Bruin et al., 1973). Within the CNS homogenates, the liberation of CO₂ from the carboxyl carbon of glycine was quantitatively coupled to the formation of serine. The presence of an endogenous inhibitor(s) within neural tissues was suggested by the non-additivity of the activities when homogenates from the various regions were combined. Moreover, homogenates of CNS tissue inhibited the GCS activity of liver homogenates, and an inverse relationship was found between the level of GCS activity in a given region of the CNS and its ability to inhibit the GCS activity of liver homogenates. This inhibition of liver activity was greatest when liver was incubated with homogenates of spinal cord (86%) and lowest when incubated with homogenates of telencephalon (20%). Because of this endogenous inhibition, the apparent activity of the GCS measured in vitro may not reflect the contribution of this enzyme system in the metabolism of glycine in vivo. Although the significance of this inhibition is not known, a possible role is discussed for the regulation of the levels in glycine and one-carbon pools within the CNS.     

DEVELOPMENT OF MITOCHONDRIAL PYRUVATE METABOLISM IN RAT BRAIN

The activities of a number of mitochondrial enzymes involved in the metabolism of pyruvate during development of the rat brain were investigated. The rates of decarboxylation of [1-¹⁴C]pyruvate to ¹⁴CO₂ via pyruvate dehydrogenase and the fixation of H¹⁴CO₃^? in the presence of pyruvate via pyruvate carboxylase by brain homogenates were very low in newborn rats. These rates increased markedly by about four-fold and 15-fold respectively during 10–35 postnatal days. The rates of the fixation of H¹⁴CO₃^? by cerebral homogenates were supported by the development of the activity of pyruvate carboxylase in rat brain. The activities of citrate synthase, aconitase, NAD-malate dehydrogenase, aspartate aminotransferase, alanine aminotransferase and phosphoenol-pyruvate carboxykinase were very low in the particulate fraction of the newborn rat brain. The activities of all these enzymes increased makedly by about three- to 10-fold during 10–35 days after birth. The activity of mitochondrial phosphoenolpyruvate carboxykinase from rat brain was not precipitated by an antibody prepared against rat liver cytosolic phosphoenolpyruvate carboxykinase suggesting that cerebral mitochondrial enzyme is immunologically different from that of the cytosolic form in hepatocytes. The significance of the development of the cerebral mitochondrial metabolism is discussed in relation to biochemical maturation of the brain.     

Effects of dietary vitamin E supplement on gracile axonal dystrophy (gad) mice

We have studied the effects of dietary vitamin E supplement on the clinical signs and pathological changes in GAD (gracile axonal dystrophy) mice. The control diet contained 2 mg of dl-alpha-tocopheryl acetate (2 I.U.) and vitamin E-supplemented diet contained 58.5 mg of dl-alpha-tocopheryl nicotinate (50 I.U.), per 100 mg of feed. The diet was given to normal (gad/+) and GAD (gad/gad) mice from 21 to 130 days of age. During the feeding, there was no improvement in clinical signs in the GAD mice fed the vitamin E-supplemented diet. The gracile nucleus of the medulla oblongata and the gracile fascicules of the spinal cord were investigated for pathology at 130 days of age, and alpha-tocopherol was also assayed in the serum, liver, brain and spinal cord at that time. There were no pathological differences in the gracile nucleus and fascicules between the GAD mice fed the control and vitamin E-supplemented diet. The alpha-tocopherol levels in the serum and target organs in the control GAD mice were not significantly different from those in control normal mice, showing that GAD mice could absorb and transport alpha-tocopherol. In the supplemented GAD mice, no significant increases in alpha-tocopherol levels were observed in the liver, brain or spinal cord. Particularly, the percentage increase of alpha-tocopherol level in the liver of GAD mice was very low in comparison with that in normal mice, even though the liver can store vitamin E. Thus it may be that the capacity to store vitamin E is lowered in GAD mice. Further studies are needed to investigate in detail the vitamin E metabolism in the mutant mice.     

Glutamic Acid Decarboxylase in Sea Lamprey (Petromyzon marinus): Characterization, Localization, and Developmental Changes

Abstract: We have carried out assays for glutamic acid decarboxylase (GAD) in homogenates of brain and spinal cord from larval and adult sea lamprey ( Petromyzon marinus ). The enzyme had similar characteristics in both stages. Optimal pH was 6.8; optimal temperature was 27–30° C; K _m at 27°C was 5 mM. GAD activity was distributed uniformly along the length of the spinal cord. Specific activities for the larval cord and brain were 26 and 63 nm CO₂/mg protein/h. respectively. The specific activities for the adult cord and brain were 29 and 236 nm CO₂/mg protein/h, respectively. Thus, the activity of cord homogenates did not change significantly between larval and adult stages, but that of the brain increased about fourfold.     

L-GLUTAMIC ACID DECARBOXYLASE IN NON-NEURAL TISSUES OF THE MOUSE

Abstract— Low levels of γ-aminobutyric acid (GABA) and of glutamic acid decarboxylase (GAD) activity have been detected in mouse kidney, liver, spleen and pancreas. Quantitation of both ¹⁴CO₂ and [¹⁴C]GABA produced in radiometric assays from [U-¹⁴CJglutamic acid has shown that measurement of ¹⁴CO₂ evolution alone is not, in all cases, a valid estimate of true GAD activity. As evidenced by increased ^,14CO₂ production upon addition of NAD and CoA to assay mixtures, radiometric assay of GAD activity in crude homogenates may yield ¹⁴CO₂ via the coupled reactions of glutamic acid dehydrogenase and a-ketoglutarate dehydrogenase. The addition of 1 mM aminooxyacetic acid (AOAA) to assays of kidney homogenates inhibited [^,14C]GABA production 92 per cent while ¹⁴CO₂ production was inhibited only 53 per cent. No evidence was found to confirm the reported existence of a second form of the enzyme, GAD II. previously described by Haber el al. (H aber B., K uriyama K. & R oberts E. (1970) Biochem. Pharmac. 19, 1119-1136). Based on sensitivity-to AOAA and chloride inhibition, the GAD activity in mouse kidney is. apparently, indistinguishable from that of neural origin.     

Susceptibility of chickens to avian encephalomyelitis virus. IV. Behavior of the virus in laying hens.

Some laying hens 6 months of age were inoculated subcutaneously or orally with a chick embryo--adapted strain of avian encephalomyelitis virus and examined for propagation of the virus in the body. When inoculated subcutaneously, the virus appeared in liver, spleen, ovarian follicle, and muscle at the site of inoculation 1 day, in kidney and lumbar part of the spinal cord 3 days, in the pancreas 5 days, in heart, duodenum, and cervical part of the spinal cord 7 days, and in the brain 11 days after inoculation. After its appearance, it increased gradually in amount in liver, spleen, pancreas, muscle at the site of inoculation, and cervical and lumbar parts of the spinal cord, but remained at a low level in any other organ. When examined 14 days after inoculation and later, it was distributed mainly in the central nervous system. It was detected from 12 of 16 organs examined. The highest virus level in each organ was 10(2.6)/0.1 g in pancreas and lumbar part of the spinal cord, which were followed by muscle at the site of inoculation (10(2.0)/0.1 g), spleen (10(1.8)/0.1 g), cervical part of the spinal cord, heart, and liver in the order listed. When inoculated orally, the virus was found sporadically in spleen, pancreas, kidney, cecum, ovarian follicle, and lumbar part of the spinal cord. The virus level was low in these organs, of which pancreas, kidney, and lumbar part of the spinal cord showed the highest virus level, or 10(1.3)/0.1 g.     

Abnormalities of neurotransmitter enzymes in Huntington's chorea

The activities ofl-glutamate decarboxylase (GAD), GABA-transaminase (GABA-T), choline acetyltransferase (CAT), and cysteic and cysteinesulfinic acids decarboxylase (CAD/CSAD) in putamen and frontal cortex in both Huntington's chorea and normal tissues were measured. The greatest difference between Huntington's and normal tissues occurred in putamen, in which the apparent CSAD activity was reduced by 85%, while no difference was observed in frontal cortex. GAD, CAD, and CAT activities were also reduced in putamen by 65%, 63%, and 42%, respectively (P<0.05). Slight reduction in the enzyme activities was also observed in frontal cortex. However, these reductions appeared to be statistically insignificant (P>0.05 in all cases). GABA-T showed little difference in both putamen and frontal cortex in Huntington's chorea and normal tissues. GAD and GABA-T from Huntington's tissues were indistinguishable from those obtained from normal tissues by double diffusion test and by microcomplement fixation test, which is capable of distinguishing proteins with a single amino acid substitution. Furthermore, the similarity of the complement fixation curves for GAD from Huntington's and normal tissues suggests that the decrease in GAD activity is probably due to the reduction in the number of GAD molecules, presumably through the loss of neurons, and not due to the inhibition or inactivation of GAD activity by toxic substances which might be present in Huntington's chorea.     

Cyclic nucleotide phosphodiesterase and protein activator in fetal rabbit tissues.

Cyclic nucleotide phosphodiesterase activity (EC 3.1.4.17) was studied in fetal and newborn rabbit brain, heart, liver, kidney, and lung. Kinetic analysis of phosphodiesterase activity from homogenates of organs from the 25-day embryo suggested the presence of a high K_m and a low K_m activity for both cyclic AMP and cyclic GMP hydrolysis. The addition of 1 μm cyclic GMP to the assay stimulated the hydrolysis of cyclic AMP by whole homogenates of liver, brain, lung, and kidney, but not heart, at all of the ages studied. The addition of micromolar levels of calcium ion stimulated cyclic GMP hydrolysis by homogenates of fetal brain, heart, and kidney, with or without added protein activator. Cyclic GMP phosphodiesterase activity was not stimulated by the addition of calcium ion in homogenates of early fetal rabbit liver and lung, but stimulation was detected in the late embryo and newborn. The presence of the heat-stable protein activator was demonstrated in brain, heart, kidney, liver, and lung tissue at all of the fetal ages studied, and in the newborn rabbit. DEAE-cellulose chromatography demonstrated the presence of three separable enzymes in brain and liver at 15 days, heart at 19 days, and lung and kidney at 25 days of gestation, with no changes in the kinetic properties of the isolated enzymes during development. These experiments suggest that all of the organs studied have the mature array of phosphodiesterases early in development, but an enzyme from liver and lung becomes sensitive to regulatory control by calcium only late in gestation.     

Tissue distribution and molecular heterogeneity of bovine thiol:protein-disulphide oxidoreductase (disulphide interchange enzyme)

1. The distribution of thiol:protein-disulphide oxidoreductase (disulphide interchange enzyme) in 17 bovine tissue extracts was determined by rocket immunoelectrophoresis and by measuring the reductive cleavage of insulin. 2. The relative concentration (per mg total protein) was found to be in the order: Pancreas greater than liver greater than lymph node greater than testes, fat tissue greater than parotid gland, brain, spleen, lung greater than small intestine, spinal cord, large intestine, kidney greater than paunch, aorta greater than skeletal muscle greater than heart. 3. The distribution of specific activity showed a similar pattern, irrespectively of whether glutathione or L-cysteine was used as cosubstrate. 4. The concentration varied 200-fold and the specific activity 400-fold between pancreas and heart muscle, respectively. 5. Crossed immunoelectrophoresis demonstrated that a fast-migrating form of the enzyme was the only one present in almost all tissues, but 15% of the enzyme in liver was a slow-migrating form and 50% in heart muscle a medium-migrating form. 6. The lung contains a species having partial immunological identity to the enzyme. 7. Purified enzyme from bovine liver has a somewhat lower mobility than the fast-migrating form in extract. 8. The results seem to support the general view that the enzyme is involved in synthesis of disulphide-bonded extracellular proteins, although the presence of the enzyme in tissues like fat, brain, spinal cord, skeletal muscle and heart indicates other cellular functions as well.     

Androgen binding in peripheral tissues of fetal rhesus macaques: effects of androgen metabolism in liver

In rhesus monkeys sexual differentiation of the brain and reproductive tract (RT) is androgen-dependent. Presumably these effects are mediated through the androgen receptor (AR). The AR has not been characterized in fetal tissues such as liver, kidney, heart, spinal cord and RT in this species. We characterized AR binding using [3H]R1881 as the ligand in cytosols from tissues obtained on days 100-138 of gestation. Scatchard analyses revealed a single, saturable, high affinity AR in liver, kidney, heart, spinal cord and RT. The apparent dissociation constant (Kd) ranged from 0.52 to 0.85 nM with no significant tissue differences. The number of AR (Bmax; fmol/mg protein) differed significantly (P less than 0.01) between tissues (liver greater than RT much greater than kidney greater than or equal to heart greater than or equal to spinal cord). Radioinert testosterone (T) and 5 alpha-dihydrotestosterone (DHT) but not androstenedione, progesterone, estradiol-17 beta, estrone or cortisol in a 50-fold molar excess inhibited [3H]R1881 binding to the AR in spinal cord, heart, kidney and RT. However, in liver only DHT competed significantly (P less than 0.01) for binding. This difference in binding of DHT vs T in the liver was further investigated by incubating liver and kidney cytosols with [3H]DHT and [3H]T at 4 degrees C. We identified the metabolic products by mobility on Sephadex LH-20 columns and reverse isotope dilution. Liver cytosols metabolized [3H]DHT to 5 alpha-androstane- 3 alpha,17 beta-diol (5 alpha-diol) and [3H]T to 5 beta-androstane-3 alpha, 17 beta-diol (5 beta-diol) at 4 degrees C. In contrast, kidney cytosols metabolized [3H]DHT while [3H]T remained unchanged. Further studies indicated that a 50-fold molar excess of 5 alpha-diol inhibited the binding of [3H]R1881 in liver cytosols by about 50% whereas the same molar concentration of 5 beta-diol had no effect. These data demonstrate the presence of AR in peripheral tissues of fetal rhesus monkeys and suggest that androgens through their receptors may affect development of these tissues. Liver cytosols are capable of metabolizing T and DHT at 4 degrees C at conditions similar to those used for measuring cytosolic AR. However, T and DHT are metabolized differently, generating different isomers which have different affinities for hepatic AR.     

Metal ion content of internal organs in the calorically restricted Wistar rat

BackgroundDespite the agreed principle that access to food is a human right, undernourishment and metal ion deficiencies are public health problems worldwide, exacerbated in impoverished or war-affected areas. It is known that maternal malnutrition causes growth retardation and affects behavioral and cognitive development of the newborn. Here we ask whether severe caloric restriction leads per se to disrupted metal accumulation in different organs of the Wistar rat.MethodsInductively coupled plasma optical emission spectroscopy was used to determine the concentration of multiple elements in the small and large intestine, heart, lung, liver, kidney, pancreas, spleen, brain, spinal cord, and three skeletal muscles from control and calorically restricted Wistar rats. The caloric restriction protocol was initiated from the mothers prior to mating and continued throughout gestation, lactation, and post-weaning up to sixty days of age.ResultsBoth sexes were analyzed but dimorphism was rare. The pancreas was the most affected organ presenting a higher concentration of all the elements analyzed. Copper concentration decreased in the kidney and increased in the liver. Each skeletal muscle responded to the treatment differentially: Extensor Digitorum Longus accumulated calcium and manganese, gastrocnemius decreased copper and manganese, whereas soleus decreased iron concentrations. Differences were also observed in the concentration of elements between organs independently of treatment: The soleus muscle presents a higher concentration of Zn compared to the other muscles and the rest of the organs. Notably, the spinal cord showed large accumulations of calcium and half the concentration of zinc compared to brain. X-ray fluorescence imaging suggests that the extra calcium is attributable to the presence of ossifications whereas the latter finding is attributable to the low abundance of zinc synapses in the spinal cord.ConclusionSevere caloric restriction did not lead to systemic metal deficiencies but caused instead specific metal responses in few organs.     

Antigenic properties of the loosely bound subnuclear fraction of rat brain

Antibodies against the loosely bound subnuclear fraction (0.35 M NaCl-extractable subnuclear fraction) of rat brain were raised in rabbits, and the distribution of the main antigenic determinants was followed among subcellular fractions of nervous tissue and among homologous nuclear preparations from different tissues. By immunofluorescence a localization restricted to the nucleus was observed, and by microcomplement fixation the antigens appeared to specifically enrich the fraction under examination, being poorly detectable in cytosol, nuclear sap, or deoxyribounucleoproteins of rat brain. No significant cross-reaction was observed by complement fixation with homologous preparations from muscle, liver, kidney, spleen, lung, or thymus of rat, whereas the 0.35 M NaCl-extracted subnuclear fraction from rat testis exhibited an immunoreactivity, although lower than that for brain proteins. After trypsin or ribonuclease treatment, the main antigenic determinants appeared to be protein in nature. The subnuclear fraction under examination, which is believed to be relevant to gene regulation, appears to contain protein antigens mainly concentrated in the nervous system.     

Specificity of oligoclonal IgG bands in sera from chronic relapsing experimental allergic encephalomyelitis guinea pigs

The specificity of oligoclonal IgG in sera from chronic relapsing EAE guinea pigs was determined by using imprint electroimmunofixation. The response of oligoclonal IgG to spinal cord and Mycobacterium tuberculosis appeared to be equal in animals sacrificed during first remission and in those sacrificed after recovery from acute EAE. In contrast, in animals sacrificed during or after the first relapse, the oligoclonal IgG seems to be directed predominantly against spinal cord. In imprint electroimmunofixation, the oligoclonal IgG specific to spinal cord did not react with guinea pig liver and kidney. In addition, activity to spinal cord could be removed from sera by absorption with spinal cord but not with kidney or liver.     

Apparent binding activity of [H]glutathione in rat central and peripheral tissues

An apparent binding activity of [³H]glutathione (GSH) was detected in the synaptic membranous preparations obtained from the rat brain. Both methionine- and leucine-enkephalins exhibited a profound diminution of the apparent binding at 100 μM in a naloxone-insensitive fashion. The retina was found to have the highest binding activity amongst various central structures examined, followed by the hypothalamus, striatum, spinal cord, midbrain, hippocampus, medulla-pons, cerebellum and cerebral cortex. In peripheral organs employed, the pituitary possessed an apparent binding activity higher than that in the retina, with progressively lower activities in the adrenal, liver, spleen, skeletal muscle and heart. No significant activity was detected in the kidney. These results suggest that specific binding sites of GSH may be located in the central and peripheral excitable tissues.     

Molecular cloning of cDNA for rat liver general acyl CoA dehydrogenase and homology between the rat liver and pig kidney enzymes

cDNA clone for general acyl CoA dehydrogenase (GAD) was isolated from a rat liver cDNA expression library in lambda gt11 using anti-pig kidney GAD antibody. Size of the isolated cDNA was estimated to be 1.5-1.6 kb. By immunological analysis of fusion protein and epitope selection, the cDNA clone was identified as that containing the GAD gene. Partial amino acid sequence deduced from nucleotide sequence of the cDNA coincided with that of the pig kidney enzyme. The antibody cross-reacted with rat liver enzyme and molecular weights of these enzyme proteins were shown to be almost the same. All these results indicate that rat liver GAD shares a common structure with pig kidney enzyme.