Evidence that the hydrophobic domain of rat renal gamma-glutamyltransferase spans the brush border membrane.

Lactoperoxidase and glucose oxidase catalyzed 125I-iodination was used to specifically label isolated rat renal brush border membrane vesicles from either side of the membrane. Autoradiography of total membrane proteins demonstrated that asymmetric labeling was achieved. Specific immunoprecipitates of aminopeptidase M, an established transmembrane protein, and of gamma-glutamyltransferase were isolated from vesicles solubilized with Triton X-100 or with papain. Following electrophoresis and autoradiography, the immunoprecipitates of the two solubilized forms of each enzyme derived from externally labeled vesicles exhibited the same intensity of labeling. In these experiments, and small subunit of the gamma-glutamyltransferase was preferentially labeled suggesting that, compared to the large subunit, it is more exposed on the external surface of the membrane. With the samples derived from internally labeled vesicles, the triton-solubilized form of each enzyme was intensely labeled, whereas the papain-solubilized forms contained insignificant amounts of radioactivity. Thus, the extent of contramembrane labeling was minimal. These experiments, the large subunit of the gamma-glutamyltransferase was preferentially labeled. The similarity of the labeling patterns obtained for aminopeptidase M and gamma-glutamyltransferase suggests that the hydrophobic domain of the two amphipathic enzymes are selectively labeled from the internal surface and that the gamma-glutamyltransferase may also be a transmembrane protein.

Isolation and characterization of the promoter region of the rat kidney-type glutaminase gene.

A lambdaEMBL3 rat genomic library was screened to clone a phage that contained the promoter region of the kidney-type mitochondrial glutaminase gene. The resulting lambdaGA1 phage contained 13.7 kb of genomic DNA that was mapped by Southern blotting and restriction analysis. The 2.22 kb and 0.83 kb SacI fragments of lambdaGA1 were sequenced and the transcription initiation site was identified by RNase mapping. The reported sequence contains 2287 bp of the promoter, the entire exon 1 (542 bp), and 223 bp of the initial intron of the glutaminase gene. The initial exon contains 141 bp of 5'-nontranslated sequence and 401 bp of coding sequence that encodes the 72-amino acid mitochondrial targeting presequence and 61 amino acids from the N-terminus of the mature 66 kDa glutaminase subunit. Various segments of the GA promoter were cloned into a chloramphenicol acetyltransferase (CAT) expression vector. The resulting GA-CAT constructs were transfected into LLC-PK(1)-F(+) kidney cells to assess the promoter function of the isolated genomic DNA. The GA(-402)CAT construct produced a 10-fold greater CAT activity than the promoter-less pCAT vector. Analysis of various deletion constructs indicated that elements located between -402 and -63 bp must act in synergy with more proximal elements to create a functional promoter. The initial 402 bp segment lacks a TATA sequence but is GC-rich and contains two CCAAT boxes and two Sp1 sites.

Immunocytochemical localization of gamma-glutamyltranspeptidase during fetal development of mouse kidney.

In the fully developed kidney, gamma-glutamyltranspeptidase is localized predominantly to the apical plasma membrane of the proximal tubules. The appearance of this activity during murine fetal nephrogenesis was quantitated using a sensitive fluorometric assay, and development of membrane polarity was assessed by immunocytochemistry. Specific activity of the transpeptidase in 13-day fetal kidney was approximately 1 mU/mg protein. Between 13-21 days of gestation, total transpeptidase activity increased 7500-fold, whereas specific activity increased 50-fold. At 13 days of gestation, gamma-glutamyltranspeptidase immunoreactivity is localized to the apical surfaces of developing renal vesicles and the proximal segment of the S-shaped tubules. The organized cell structures have tight tubular junctions but lack a well-defined brush-border membrane. By 15 days of gestation, immunostaining of the apical surface of developing proximal segments is more prominent, and slight reactivity of the basolateral membrane is evident. By 17 days of gestation, the kidney is organized into discrete zones. The large increase in gamma-glutamyltranspeptidase activity correlates with the appearance of increased immunostaining of the developing brush-border membranes of the proximal tubules contained in the inner cortex. A very similar although somewhat delayed pattern of appearance of transpeptidase activity and immunostaining was observed in metanephric organ culture. Induction of proximal tubular cyst formation had no effect on the increase in transpeptidase activity that occurred during organotypic nephrogenesis.

pH regulation of renal gene expression.

The increase in intracellular pH (pHi) associated with various tumour cells triggers changes in gene expression. Similar adaptations also occur as part of the physiological response to changes in acid base balance. For example, during metabolic acidosis, increased renal ammoniagenesis and bicarbonate synthesis are sustained by the increased expression of various transport proteins and key enzymes of glutamine metabolism. In rat kidney, increased expression of the mitochondrial glutaminase (GA) and glutamate dehydrogenase (GDH) results from stabilization of their respective mRNAs. The 3'-untranslated region (UTR) of the GA mRNA contains a direct repeat of an 8-base AU sequence that functions as a pH-response element. This sequence exhibits a high affinity and specificity for z-crystallin. The same protein binds to two separate, but homologous, 8-base AU sequences within the 3'-UTR of the GDH mRNA. The apparent binding activity of z-crystallin is increased significantly during onset of metabolic acidosis. Thus, increased binding of z-crystallin may initiate the pH-responsive stabilization of the two mRNAs. In contrast, induction of the phosphoenolpyruvate carboxykinase (PEPCK) gene occurs at the transcriptional level. In LLC-PK1-FBPase+ kidney cells, a decrease in pHi leads to activation of the p38 stress-activated protein kinase and subsequent phosphorylation of ATF-2. This transcription factor binds to the CRE-1 element within the promoter of the PEPCK gene to enhance transcription. Similar mechanisms may contribute to altered gene expression in tumour cells.

Isolation, characterization and expression of a human brain mitochondrial glutaminase cDNA.

Various cDNAs that encode overlapping portions of the full-length human brain glutaminase (GA) cDNA were cloned and sequenced. The overall nucleotide sequence of hGA has a very high degree of identity with that of the rat kidney-type GA cDNA (77.4%) and the known portion of the cDNA that encodes the 5.0-kb porcine GA mRNA (81.1%). The identity is even more remarkable at the amino acid level, particularly in the C-terminal half where the three proteins share a 99.7% sequence identity. The hGA cDNA encodes a 73,427-Da protein that contains an N-terminal mitochondrial targeting signal and retains the primary proteolytic cleavage site characterized for the cytosolic precursor of the rat renal mitochondrial glutaminase. The entire coding region was assembled through the use of unique restriction sites and cloned into a baculovirus. Sf9 cells infected with the recombinant virus express high levels of properly processed and active glutaminase. Thus, expression of the isolated hGA cDNA should provide a means to purify large amounts of the mitochondrial glutaminase, a protein that catalyzes a key reaction in the metabolism of glutamine and the synthesis of important excitatory and inhibitory neurotransmitters.

Localization of elevated glutaminase immunoreactivity in small DRG neurons.

Glutamate has long been considered to be a neurotransmitter candidate in vertebrate spinal sensory nerve cells. We report here the first immunohistochemical evidence in support of this hypothesis. We find that up to 30% of the moderately small dorsal root ganglion neurons in the rat contain elevated levels of glutaminase immunoreactivity. This enzyme, which mediates the synthesis of glutamate from glutamine, is not found at these high levels in large diameter neurons of the same ganglia. In contrast, another enzyme associated with glutamate metabolism, aspartate aminotransferase, is rather uniformly distributed within neurons of the sensory ganglia. These data define a subpopulation of sensory neurons which appear to contain an elevated capacity to synthesize glutamate through the glutamine cycle and suggest that glutaminase immunoreactivity may be an indicator of glutamatergic function in some nerve cells.

Immunocytochemical localization of glutaminase-like and aspartate aminotransferase-like immunoreactivities in the rat and guinea pig hippocampus.

There is considerable evidence that pathways of the hippocampus use an excitatory amino acid as transmitter. We have attempted to immunocytochemically identify excitatory amino acid neurons in the hippocampus of the rat and guinea pig using antiserum to glutaminase and antiserum to aspartate aminotransferase, which have been proposed as markers for aspartergic/glutamergic neurons. Glutaminase-like immunoreactivity was seen in granule cells in the dentate gyrus and fibers and puncta associated with the mossy fiber pathway in the hilus and stratum lucidum of the hippocampus. At the ultrastructural level, glutaminase-like immunoreactivity was observed in mossy fiber terminals in the stratum lucidum. Glutaminase-like immunoreactivity was also seen in pyramidal cells in regio inferior and regio superior and in cells in layer two of the entorhinal cortex. Schaffer collateral terminals, commissural fiber terminals and perforant pathway terminals were not seen at the light microscopic level. Glutaminase-like immunoreactivity is thus found in the cell bodies of proposed excitatory amino acid neurons of hippocampal pathways, but does not appear to label all terminals. Aspartate aminotransferase-like immunoreactivity was not seen in any cells, fibers or terminals in the rat or guinea pig hippocampus.

Isolation of a cDNA for rat brain glutaminase.

A single phage was isolated from a lambda gt11 rat brain cDNA library by screening with antibodies prepared against rat renal glutaminase. Partial proteolysis of the fusion protein produced by a lysogen of the isolated phage generated a series of immunoreactive peptides that co-migrated with those derived from the purified brain glutaminase. The cDNA has a single open reading frame which encodes 326 amino acids that are in frame with beta-galactosidase. A 72-kDa protein, corresponding in size to the precursor of mitochondrial glutaminase, was immunoprecipitated from the translation products of rat renal mRNA that selectively hybridized to the cDNA. A probe made from the glutaminase cDNA detected an mRNA about 6 kb in length. This mRNA was present in rat brain and normal kidney RNA, increased 6-fold in acidotic kidney RNA, but was not detectable in liver RNA.

Immunocytochemical localization of glutaminase-like immunoreactivity in the auditory nerve.

The immunocytochemical localization of glutaminase, which we have proposed as a marker for excitatory amino acid neurotransmitters was determined in the guinea pig auditory nerve. Glutaminase-like immunoreactivity was seen in auditory nerve terminals in the cochlear nucleus and in the cell bodies of the auditory nerve in the cochlea. This staining was seen in type I and not type II spiral ganglion cells. Glutaminase-like immunoreactivity was also observed in granule cells in the cochlear nucleus.

Renal response to metabolic acidosis: role of mRNA stabilization.

The renal response to metabolic acidosis is mediated, in part, by increased expression of the genes encoding key enzymes of glutamine catabolism and various ion transporters that contribute to the increased synthesis and excretion of ammonium ions and the net production and release of bicarbonate ions. The resulting adaptations facilitate the excretion of acid and partially restore systemic acid-base balance. Much of this response may be mediated by selective stabilization of the mRNAs that encode the responsive proteins. For example, the glutaminase mRNA contains a direct repeat of 8-nt AU sequences that function as a pH-response element (pHRE). This element is both necessary and sufficient to impart a pH-responsive stabilization to chimeric mRNAs. The pHRE also binds multiple RNA-binding proteins, including zeta-crystallin (zeta-cryst), AU-factor 1 (AUF1), and HuR. The onset of acidosis initiates an endoplasmic reticulum (ER)-stress response that leads to the formation of cytoplasmic stress granules. zeta-cryst is transiently recruited to the stress granules, and concurrently, HuR is translocated from the nucleus to the cytoplasm. On the basis of the cumulative data, a mechanism for the stabilization of selective mRNAs is proposed. This hypothesis suggests multiple experiments that should define better how cells in the kidney sense very slight changes in intracellular pH and mediate this essential adaptive response.

Role of mitochondrial glutaminase in rat renal glutamine metabolism.

During normal acid-base balance, the kidney extracts very little of the plasma glutamine. However, during metabolic acidosis, as much as one third of the plasma glutamine is extracted and metabolized in a single pass through this organ. The substantial increase in renal utilization occurs solely within the proximal convoluted tubule and is sustained by compensating adaptations in the intraorgan metabolism of glutamine. The primary pathway for renal glutamine metabolism involves its transport into mitochondria and its deamidation and deamination by glutaminase (GA) and glutamate dehydrogenase (GDH), respectively. The resulting ammonium ions are excreted predominantly in the urine where they function as expendable cations to facilitate the excretion of acids. The resulting alpha-ketoglutarate is further metabolized to phosphoenolpyruvate and subsequently to glucose or CO2. The intermediate steps yield two bicarbonate ions that are selectively transported into the venous blood to partially compensate the metabolic acidosis. In rat kidney, this adaptation is sustained in part by the cell-specific induction of the glutaminase that results primarily from stabilization of the GA mRNA. The 3'-nontranslated region of the GA mRNA contains a direct repeat of an 8-base AU-sequence that functions as a pH-response element. This sequence exhibits a high affinity and specificity for zeta (z)-crystallin. The same protein binds to two separate, but homologous, 8-base AU-sequences within the 3'-nontranslated region of the GDH mRNA. The apparent binding activity of z-crystallin is increased significantly during onset of metabolic acidosis. Thus, increased binding of z-crystallin may initiate the pH-responsive stabilization of the two mRNAs.

NAD+-dependent ADP-ribosyltransferase in renal brush-border membranes.

Oxidized nicotinamide adenine dinucleotide (NAD+) in cytosol may interact with renal brush-border membranes (BBM) and inhibit BBM phosphate transport. The possible mechanism of interaction was investigated in the present study. Incubation of BBM with [adenine-3H]NAD+ led to acid-stable binding of 3H to the BBM, in contrast there was no binding of 14C when [carbonyl-14C]NAD+ was used. The data are consistent with an ADP-ribosylation mechanism involving transfer of ADP-ribose from NAD+ to BBM. This was confirmed by using [adenylate-32P]NAD+ and by the release of bound 32P in the form of 5'-[32P]AMP when the BBM were treated with snake venom phosphodiesterase. After gradient centrifugation of BBM the ADP-ribosyltransferase was recovered at the same density as known BBM enzymes, indicating that ADP-ribosyltransferase is an intrinsic BBM component and not a contaminant. These findings indicate that cytosolic NAD+ may be used for ADP-ribosylation of BBM proteins and that this may be a mechanism for regulating the BBM phosphate transport system.

Effect of acute alterations in acid-base balance on rat renal glutaminase and phosphoenolpyruvate carboxykinase gene expression.

During chronic acidosis, the levels of the rat renal mRNAs that encode the mitochondrial glutaminase (GA) and cytosolic phosphoenolpyruvate carboxykinase (PCK) are increased 6-fold. Following acute recovery of chronic acidosis, the levels of the two mRNAs are rapidly and coordinately decreased, returning to normal within 13-17 h. In contrast, the increases in GA and PCK mRNAs during acute onset of acidosis occur with very different kinetics. The increase in PCK mRNA occurs rapidly and reaches a maximum within 7 h, whereas the GA mRNA is increased after a 4-7-h lag and then plateaus at 14-17 h. Treatment with dexamethasone or with cAMP analogs significantly increases the level of renal PCK mRNA but has no effect on the level of GA mRNA. Nuclear run-on experiments indicate that the acute induction of PCK mRNA is primarily due to an increased rate of transcription. However, transcription of GA mRNA is unaffected by acute acidosis. Therefore, the changes in the two mRNAs are temporally coordinated but occur through different mechanisms. Furthermore, the inductive effects of acidosis are not mediated solely through glucocorticoid or cAMP regulatory elements.

Properties of rat kidney glutaminase enzymes and their role in renal ammoniagenesis.

Rat kidney contains two distinct glutaminase activities; the mitochondrial phosphate-dependent glutaminase and a second glutaminase activity associated with the brush border membrane which is maleate-activated and phosphate-independent. It has recently been shown that the phosphate-independent glutaminase is a partial reaction of gamma-glutamyl transpeptidase and that maleate activates this enzyme by blocking transpeptidation. The gamma-glutamyl transpeptidase in other rat tissues is also affected by maleate. This enzyme has at least a 100-fold greater affinity for glutathione or for glutathione derivatives than for glutamine, suggesting that under physiological conditions glutathione is the preferred substrate. With either type of substrate, maleate affects the Vmax of the reaction but not the Km. These findings suggest that this enzyme probably contributes very little to renal ammoniagenesis. In contrast, the phosphate-dependent glutaminase, whose activity increases 20 to 30-fold in the proximal convoluted tubule cells in response to metabolic acidosis, probably contributes significantly to renal ammoniagenesis. We have purified the rat kidney phosphate-dependent glutaminase and compared the phosphate activation and the phosphate-induced dimerization of the Tris form of this enzyme. There is an excellent correlation between increased activity and extent of dimerization as phosphate concentration is increased. The molecular weights of the Tris form are 1600000 and 316000 in the absence and presence of -1 M NaPO4, respectively. At saturating concentration of phosphate, increasing concentrations of chloride ion similarly reverse both activation and dimerization. These observations suggest that only the dimer form of the Tris enzyme is active.

Phosphate-independent glutaminase from rat kidney. Partial purification and identity with gamma-glutamyltranspeptidase.

Phosphate-independent glutaminase can be quantitatively solubilized from a microsomal preparation of rat kidney by treatment with papain. Subsequent gel filtration and chromatography on quaternary aminoethyl (QAE)-Sephadex and hydroxylapatite yield a 200-fold purified preparation of this glutaminase. The purified enzyme also hydrolyzes gamma-glutamylhydroxamate and exhibits substrate inhibition at high concentrations of either glutamine or gamma-glutamyhydroxamate, which is partially relieved by increasing concentrations of maleate. Rat kidney phosphate-independent glutaminase reaction is catalyzed by the same enzyme which catalyzes the gamma-glutamyltranspeptidase reaction. The ratio of glutaminase to transpeptidase activities remained constant throughout a 200-fold purification of this enzyme. The observation that the phosphate0independent glutaminase and gamma-glutamyltranspeptidase activities exhibit coincident mobilities during electrophoresis, both before and after extensive treatment with neuraminidase, strongly suggests that both reactions are catalyzed by the same enzyme. This conclusion is strengthened by the observation that maleate and various amino acids have reciprocal effects on the two activities. Maleate increases glutaminase activity and blocks transpeptidation, whereas amino acids activate the transpeptidase but inhibit glutaminase activity. In contrast, the addition of both maleate and alanine resulted in a strong inhibition of both activities. Both activities exhibit a similar distribution in the various regions of the kidney. Recovery of maximal activities in the outer stripe region of the medulla is consistent with previous quantitative microanalysis which indicated that this glutaminase activity is localized primarily in the proximal straight tubule cells. The glutaminase and transpeptidase activities have different pH optima. Examination of the product specificity suggests that decreasing pH also promotes glutaminase activity and that below pH 6.0, this enzyme functions strictly as a glutaminase. Because of the localization of this activity on the brush border membrane, these resuts are consistent with the possibility that the physiological conditions induced by metabolic acidosis could convert this enzyme from a broad specificity transpeptidase to a glutaminase. Therefore, this enzyme could contribute to the increased renal synthesis of ammonia from glutamine which is observed during metabolic acidosis.