Ingeborg Aa. Torgner

Kinetics and localization of brain phosphate activated glutaminase

The cellular concentration of phosphate, the main activator of phosphate activated glutaminase (PAG) is rather constant in brain and kidney. The enzyme activity, however, is modulated by a variety of compounds affecting the binding of phosphate, such as glutamate, calcium, certain long chain fatty acids, fatty acyl CoA derivatives, members of the tricarboxylic acid cycle and protons (Kvamme et al. [2000] Neurochem. Res. 25:1407–1419). Therefore, the kinetic and allosteric properties of the enzyme are essential for regulating the enzyme activity in situ, especially because the enzymically active pool of PAG is assumed to have an external localization in the inner mitochondrial membrane, being exposed to cytosolic variation in the content of effectors. This has largely been overlooked. A hypothetical model for the allosteric interactions based on the sequential induced fit allosteric model by Koshland et al. ([1966] Biochemistry 5:365–385) is presented. Furthermore, it has been generally accepted that there exist only two isoforms of PAG, the kidney PAG that is similar to brain PAG, and the liver PAG. Therefore, the immunoreactivity of brain cells against kidney PAG antibodies has been considered a measure of PAG protein. Gomez‐Fabre et al. ([ 2000 ] Biochem. J. 345:365–375) recently found, however, that a PAG mRNA from human breast cancer ZR75 cells is present in human brain and liver, but not in the kidney. We observed only traces of PAG immunoreactivity in cultured astrocytes and cultured neuroblastoma cells, regardless whether antibodies against the C‐ and N‐termini of kidney PAG or antibodies against liver PAG were used, but considerable enzyme activity, demonstrating hitherto unknown isoforms of PAG (Torgner et al. [ 2001 ] FEBS Lett. 268(Suppl 1):PS2–031).

Phosphate-Activated Glutaminase and Mitochondrial Glutamine Transport in the Brain

A review of the properties of purified and tissue bound phosphate activated glutaminase (PAG) in brain and kidney (pig and rat) is presented, based on kinetic, electron microscopic and immunocytochemical studies. PAG is a mitochondrial enzyme and two pools can be separated, a soluble and membrane associated one. Intact mitochondria appear to express PAG accessible only to the outer phase of the inner mitochondrial membrane. This PAG has properties similar to that of the membrane fraction and polymeric form of purified enzyme. PAG in the soluble fraction has properties similar to that of the monomeric form of purified enzyme and is assumed to be dormant due to the high matrix concentration of the inhibitor glutamate. A hypothetical model for the localization of PAG in the mitochondria is presented. The activity of PAG in vivo is assumed to be regulated by cytosolic glutamate and other compounds, that affect the activation by phosphate. Glutamine is transported into brain and kidney mitochondria by a protein catalyzed energy requiring process, which may be mediated by more than one protein. There is no correlation between glutamine hydrolysis and transport.

The orientation of phosphate activated glutaminase in the inner mitochondrial membrane of synaptic and non-synaptic rat brain mitochondria

When rat brain synaptic and non-synaptic mitochondria were incubated with [14C]glutamine, [14C]glutamate was rapidly released to the incubation medium, and the release was stimulated by phosphate, whereas [14C]glutamate accumulated very slowly in the mitochondria and independently of the addition of phosphate. The specific activity of [14C]glutamate (dpm.nmol glutamate-1) in the incubation medium quickly reached the level of added [14C]glutamine, but the specific activity of [14C]glutamate in the mitochondria was found to be only 10-15% of that level. This indicates that glutamine-derived glutamate was released directly to the incubation medium, without being mixed with a general pool of endogenous glutamate in the mitochondria. Furthermore, there was no correlation between rate of glutamine hydrolysis and the uptake of glutamine into the mitochondria, as measured by the uptake of [3H]glutamine and glutamine induced mitochondrial swelling when calcium plus phosphate or asparagine were added. Glutamine hydrolysis was also not stimulated by partial disruption of the mitochondria following sonication, which should be expected if the rate of glutamine hydrolysis were limited by glutamine uptake. In addition, glutamine hydrolysis was strongly inhibited by mersalyl which is known to be impermeable to the inner mitochondrial membrane. Moreover, it is indicated that the enzyme was not an integral membrane protein. Thus, following fractionation of a Triton X-114 extract of brain synaptosomes, a major fraction of both the protein, as measured by immunoblot technique, and the enzyme activity were detected in the water phase. Our results therefore indicate that the whole molecule of phosphate activated glutaminase is externally localized in the inner mitochondrial membrane.

Developmental change of endogenous glutamate and gamma-glutamyl transferase in cultured cerebral cortical interneurons and cerebellar granule cells, and in mouse cerebral cortex and cerebellum in vivo

The developmental change of endogenous glutamate, as correlated to that of gamma-glutamyl transferase and other glutamate metabolizing enzymes such as phosphate activated glutaminase, glutamate dehydrogenase and aspartate, GABA and ornithine aminotransferases, has been investigated in cultured cerebral cortex interneurons and cerebellar granule cells. These cells are considered to be GABAergic and glutamatergic, respectively. Similar studies have also been performed in cerebral cortex and cerebellum in vivo. The developmental profiles of endogenous glutamate in cultured cerebral cortex interneurons and cerebellar granule cells corresponded rather closely with that of gamma-glutamyl transferase and not with other glutamate metabolizing enzymes. In cerebral cortex and cerebellum in vivo the developmental profiles of endogenous glutamate, gamma-glutamyl transferase and phosphate activated glutaminase corresponded with each other during the first 14 days in cerebellum, but this correspondence was less good in cerebral cortex. During the time period from 14 to 28 days post partum the endogenous glutamate concentration showed no close correspondence with any particular enzyme. It is suggested that gamma-glutamyltransferase regulates the endogenous glutamate concentration in culture neurons. The enzyme may also be important for regulation of endogenous glutamate in brain in vivo and particularly in cerebellum during the first 14 days post partum. Gamma-glutamyl transferase in cultured neurons and brain tissue in vivo appears to be devoid of maleate activated glutaminase.

Glutamine transport in brain mitochondria.

Gln is transported into rat brain synaptic and non-synaptic mitochondria by a protein catalyzed process. The uptake is significantly higher in synaptic than in non-synaptic mitochondria. The transport is inhibited by the amino acids Glu, Asn and Asp, and by the TCA cycle intermediates succinate, malate and 2-OG. The inhibition by 2-OG is counteracted by AOA and is therefore assumed to be due to transamination of 2-OG, whereby Glu is formed. This presumes that Glu also binds to an inhibitory site on the matrix face of the inner membrane. The transport is complex and cannot be explained by the simple uniport mechanism which has been proposed for renal (Schoolwerth and LaNoue, 1985), and liver mitochondria (Soboll et al., 1991). Thus, Gln transport is stimulated by respiration and by the proton electrochemical gradient. Since it is indicated that both the neutral Gln zwitterion and the Gln anion are transported, there are probably different uptake mechanisms, but not necessarily different carriers. Gln may be transported by an electroneutral mechanism as a proton compensated anion, as well as electrophoretically as a zwitterion with a proton, and probably also by diffusion as a zwitterion. The properties of the brain mitochondrial Gln uptake mechanisms are also not identical with those of a purified renal Gln transporter. It is possible that the Gln transport is controlled by more than one protein, which may be situated on distinct species in a heterogeneous mitochondrial population. Since Gln is assumed to participate in energy production as well as in the synthesis of nucleic acid components and proteins in brain mitochondria, the control of Gln uptake in these organelles may be important.

Inhibition of glutamine transport in rat brain mitochondria by some amino acids and tricarboxylic acid cycle intermediates

Glutamine transport into rat brain synaptic and non-synaptic mitochondria has been monitored by the uptake of [3H]glutamine and by mitochondrial swelling. The concentration of glutamate in brain mitochondria is calculated to be high, 5–10 mM, indicating that phosphate activated glutaminase localized inside the mitochondria is likely to be dormant and the glutamine taken up not hydrolyzed. The uptake of [3H]glutamine is largely stereospecific. It is inhibited by glutamate, asparagine, aspartate, 2-oxoglutarate and succinate. Glutamate inhibits this uptake into synaptic and non-synaptic mitochondria by 95 and 85%, respectively. The inhibition by glutamate, asparagine, aspartate and succinate can be explained by binding to an inhibitory site whereas the inhibition by 2-oxoglutarate is counteracted by aminooxyacetic acid, which indicates that it is dependent on transamination. The glutamine-induced swelling, a measure of a very low affinity uptake, is inhibited by glutamate at a glutamine concentration of 100 mM, but this inhibition is abolished when the glutamine concentration is raised to 200 mM. This suggests that the very low affinity glutamine uptake is competitively inhibited by glutamate. Furthermore, glutamine-induced swelling is inhibited by 2-oxoglutarate, succinate and malate, similarly to that of the [3H]glutamine uptake. The properties of the mitochondrial glutamine transport are not identical with those of a recently purified renal glutamine carrier.

Glutamine Transport in Rat Brain Synaptic and Non-Synaptic Mitochondria

Glutamine transport into rat brain mitochondria (synaptic and non-synaptic) was monitored by the uptake of [3H]glutamine as well as by mitochondrial swelling. The uptake is inversely correlated to medium osmolarity, temperature-dependent, saturable and inhibited by mersalyl, and glutamine is upconcentrated in the mitochondria. These results indicate that glutamine is transported into an osmotically active space by a protein catalyzed mechanism. The uptake is slightly higher in synaptic mitochondria than in non-synaptic ones. It is inhibited both by rotenone and the protonophore carbonyl cyanide p-trifluoromethoxyphenylhydrazone, the latter at pH 6.5, showing that the transport is activated by an electrochemical proton gradient. The K+/H+ ionophore nigericin also inhibits the uptake at pH 6.5 in the presence of external K+, which indicates that glutamine, at least in part, is taken up by a proton symport transporter. In addition, glutamine uptake as measured by the swelling technique revealed an additional glutamine transport activity with at least 10 times higher Km value. This uptake is inhibited by valinomycin in the presence of K+ and is thus also activated by the membrane potential. Otherwise, the two methods show similar results. These data indicate that glutamine transport in brain mitochondria cannot be described by merely a simple electroneutral uniport mechanism, but are consistent with the uptake of both the anionic and the zwitterionic glutamine.

Phosphate-activated glutaminase in the crude mitochondrial fraction (P2 fraction) from human brain cortex.

Abstract The kinetics and other properties of phosphate‐activated glutaminase have for the first time been studied in the crude mitochondrial fraction (P2 fraction) from human brain. The enzyme is for unexplained reasons inactivated postmortem. The enzyme activity decreases by storing the tissue or homogenate at 37°. The inactivation is not caused by formation of a dialysable inhibiting compound. No large proteolytic degradation has occurred, since the phosphate‐activated glutaminase‐like immunoreactive band did not disappear during the storage. The molecular weight of the subunit of the enzyme as determined by immunoblots of sodium dodecyl sulfate‐treated homogenates from human brain is estimated to be approximately 64 K. The enzyme has been shown to have a pH optimum of 8.6; it is activated by phosphate, inhibited by glutamate, and partially inhibited by ammonia. Double‐inverse plots of enzyme activity against phosphate are concave‐upward, and more so in the presence of an inhibitor. The inhibition by glutamate ap pears to be noncompetitive with the substrate glutamine, and competitive with the activator phosphate. These kinetic properties are not significantly different from our earlier observations concerning phosphate‐activated glutaminase from pig brain and pig kidney.

Phosphate activated glutaminase-like immunoreactivity in the nervous system from different species and in different neuronal cell types and in astrocytes

Using antibodies against pig brain phosphate activated glutaminase, the enzyme appears to be rather conservative as we have observed immuno- staining in the brain from all species investegated [pig, cow, rabbit, rat, mouse, man, fish (cod and salmon) and bird (chicken)]. In addition, phosphate activated glutaminase from cultured mouse cerebral cortex inter- neurons (mainly GABA-ergic), cerebellar granule cells (glutamatergic) and astrocytes stained in an analogous manner. However, no phosphate activated glutaminase-like immunostaining was found in lobster ganglion. yeast and E. coli. Using the Western blotting technique, phosphate activated glutaminase from dodecyl sulfate treated samples from all the above mentioned preparations revealed a MW close to 64 K(d). The MW is similar to the MW of the subunit of phosphate activated glutaminase in a highly purified pig brain preparation, The Western blotting technique seems to be well suited to identify phosphate activated glutaminase-like immunoreactivity in different tissues.