Intranephron heterogeneity of ammoniagenesis and gluconeogenesis in rats

Induction and targeting of the glutamine transporter SN1 to the basolateral membranes of cortical kidney tubule cells during chronic metabolic acidosis suggest a role in pH regulation

During chronic metabolic acidosis (CMA), the plasma levels of glutamine are increased and so is glutamine metabolism in the kidney tubule cells. Degradation of glutamine results in the formation of ammonium (NH(4)(+)) and bicarbonate (HCO(3)(-)) ions, which are excreted in the pre-urine and transported to the peritubular blood, respectively. This process contributes to counteract acidosis and to restore normal pH, but the molecular mechanism, the localization of the proteins involved and the regulation of glutamine transport into the renal tubular cells, remains unknown. SN1, a Na(+)- and H(+)-dependent glutamine transporter has previously been identified molecularly, and its mRNA has been detected in tubule cells in the medulla of the kidney. Now shown is the selective targeting of the protein to the basolateral membranes of the renal tubule cells of the S3 segment throughout development of the normal rat kidney. During CMA, SN1 expression increases five- to six-fold and appears also in cortical tubule cells in parallel with the increased expression and activity of phosphate-activated glutaminase, a mitochondrial enzyme involved in ammoniagenesis. However, SN1 remains sorted to the basolateral membranes. The unique ability of SN1 to change transport direction according to physiologic changes in transmembrane gradients of [glutamine] and pH and its sorting to the basolateral membranes and the presence of a putative pH responsive element in the 3' untranslated region (UTR) of the gene (supported here by the demonstration in CMA kidney of a protein that binds SN1 mRNA) are conducive to the function of this transporter in pH regulation.

Glutamate transport and renal function

Brush border gamma-glutamyltransferase-glutaminase activity and the high-affinity glutamate transporter EAAC1 function as a unit in generating and transporting extracellular glutamate into proximal tubules as a signal that modulates intracellular glutamine/glutamate metabolism, paracellular permeability, and urinary acidification. The reported presence of a second glutamate transporter, GLT1, on the antiluminal tubule surface points to specific functional roles for each subtype in physiological and pathophysiological processes.

Localization of the high-affinity glutamate transporter EAAC1 in rat kidney

Most amino acids filtered by the glomerulus are reabsorbed in the kidney via specialized transport systems. Recently, the cDNA encoding a high-affinity glutamate transporter, EAAC1, has been isolated and shown to be expressed at high levels in the kidney. To determine the potential role of EAAC1 in renal acidic amino acid reabsorption, the distribution of EAAC1 mRNA and protein in rat kidney was examined. In situ hybridization revealed that EAAC1 mRNA is expressed predominantly in S2 and S3 segments of the proximal tubules and at low levels in the inner stripe of outer medulla and inner medulla. Polyclonal antibodies raised against the carboxy terminus of EAAC1 recognized a single band of approximately 70 kDa on Western blots of membrane protein from kidney cortex and medulla. Immunofluorescence microscopy revealed intense signals in the luminal membrane of S2 and S3 segments and weaker signals in S1 segments, descending thin limbs of long-loop nephrons, medullary thick ascending limbs, and distal convoluted tubules. These results are consistent with EAAC1 encoding the previously described apical high-affinity glutamate transporter in the kidney that mediates reabsorption of acidic amino acids in tubules beyond early proximal tubule S1 segments. Potential additional roles of EAAC1 in acid/base balance, cell volume regulation, and amino acid metabolism are discussed.

Nephrotoxicity assessment by measuring cellular ATP content. I. Substrate specificities in the maintenance of ATP content in isolated rat nephron segments

To clarify the characteristics of cellular ATP synthesis in individual nephron segments for assessing nephrotoxicity of chemicals, cellular ATP content was measured by the luciferin/luciferase system under various conditions using intact nephron segments isolated from male Sprague-Dawley rats. Increasing the duration of collagenase treatment of kidney slices significantly lowered the cellular levels of ATP newly synthesized from 2 mM glutamine in PST at 37 degrees C over 30 min (p less than 0.01). The tubular incubation time significantly affected the cellular ATP content in the early and middle portions (S2) of the proximal tubule (p less than 0.05 and p less than 0.01, respectively) over 20 min and in the late proximal tubule over 10 min. Among numerous substrates tested, such as D-glucose, glutamine, pyruvate, DL-lactate, and beta-hydroxybutyrate, the substrate utilization for maintaining cellular ATP content was entirely variable according to each nephron segment. Pyruvate and glutamine were the best substrates in the proximal tubule. On the other hand, ATP production from glutamine was less than that from the other substrates in the distally located nephron segments: medullary and cortical thick ascending limbs of Henle's loop (MAL and CAL, respectively), distal tubule, cortical and medullary collecting tubules (CCT and MCT, respectively). In general, glucose, pyruvate, and lactate appear to be equivalent in maintaining ATP content in the distal segments of renal tubules. A monovalent cation ionophore, monensin, at 10 micrograms/ml decreased the cellular ATP content in MAL, CAL, and MCT significantly. Mercuric chloride (HgCl2) was used as a model compound to study nephrotoxicity by investigating its effects on cellular ATP metabolism in microdissected nephron segments. HgCl2 at 1 x 10(-6) M significantly decreased ATP content only in S2 (p less than 0.05), clearly demonstrating S2 to be the most sensitive segment within the nephron. These results indicate that measurement of cellular ATP content would be a useful method forecasting the intrarenal toxic site and potency of possible nephrotoxic chemical compounds.

Intra- and inter-nephron heterogeneity of ammoniagenesis in rats: effects of chronic metabolic acidosis and potassium depletion

In order to determine intra- and inter-nephron heterogeneity of ammoniagenesis, ammoniagenic activity in microdissected nephron segments of control, acidotic and potassium (K)-depleted rats was examined. Intranephron distribution of ammoniagenic activity in control rats revealed the highest amount at the second segment of the proximal tubule (S2). Chronic metabolic acidosis induced ammoniagenesis markedly at the first segment of the proximal tubule (S1) by 235% and the thick ascending limb of Henle's loop by 198% and moderately at the S2 by 49%. K-depletion increased ammonia production significantly in the S1 by 298% and the S2 by 107%, which is a pattern quite similar to the result of chronic metabolic acidosis. Ammonia production in K-depletion was also increased in the cortical and medullary collecting tubule by 71% and 102%, respectively, probably due to increases in protein amounts (41% and 158%, respectively) there. To evaluate inter-nephron heterogeneity of ammoniagenesis, ammonia formation from glutamine in the S1 of superficial (SF) and juxtamedullary (JM) nephrons was examined. Although there was no difference in ammonia production between SF-S1 and JM-S1 in control rats, ammonia production in SF-S1 was significantly higher than that in JM-S1 in both metabolic acidosis and K-depletion. From these studies, we conclude: The increase of ammonia production in the proximal tubule was quite similar in both acidosis and K-depletion, suggesting that the main trigger of ammoniagenesis in both conditions might be a reduction of intracellular pH. SF-S1 was the nephron most reactive to acidosis and K-depletion. JM nephrons could be considered to be important not for ammonia production but for ammonia secretion.

Intra- and inter-nephron heterogeneity of gluconeogenesis in the rat: effects of chronic metabolic acidosis and potassium depletion

The intra- and inter-nephron heterogeneity of renal gluconeogenesis within rat proximal tubules and the effects of chronic metabolic acidosis and chronic potassium(K)-depletion were studied using isolated proximal tubules of rats by directly measuring glucose synthesized. The gluconeogenic activity from pyruvate and glutamine in control rats was almost limited to within the early proximal tubule (S1: 45.4 +/- 5.7 pmol/mm/60 min from pyruvate; 58.0 +/- 6.0 from glutamine). Very low, but detectable gluconeogenesis was observed in the middle portion of the proximal tubule (S2: 9.9 +/- 2.2 from pyruvate; 4.8 +/- 1.1 from glutamine). The rate of glucose production in the terminal proximal tubule (S3) was negligible. Furthermore, gluconeogenesis from glutamine of superficial (SF) nephrons was significantly higher than that of juxtamedullary (JM) ones, whereas no difference was seen in gluconeogenesis from pyruvate. In acidotic and K-depleted rats, significant increase could be seen in S1 and S2, but the increase in S3 was not significant. By the serial determination in acidosis, the glucose production from both substrates was found to be the highest at the second 1 mm segment from the glomerulus, and it decreased downward along the proximal tubule. In acidosis, glucose production from both substrates in SF nephrons and that from glutamine in JM ones were elevated significantly compared with the control, but that from pyruvate in JM nephrons did not change. These results suggest that S1 of the SF nephron plays the most important role in gluconeogenesis in the control, whereas S1 of the JM nephron and S2 contribute to gluconeogenesis in acidotic and/or possibly K-depleted rats.

Fate of intraluminal glutamine in the perfused renal tubule

To determine the fate of intraluminal glutamine and specifically the role of brush border gamma glutamyltransferase in its hydrolysis and reabsorption, proximal convoluted tubules of rabbits were isolated and perfused with an artificial ultrafiltrate containing 1 mM 14C-glutamine and 3H-PEG as a volume absorption marker. The tubules, average length 0.80 +/- 0.09 mm, were bathed in perfusate containing albumin, 6.5 percent but no glutamine. Aliquots of collectate and bathing media were monitored for total 14C counts while the distribution of radioactive 14C between glutamine and glutamate in the collectate was determined by separation on a Dowex X8 formate form ion-exchange column. After 3 ten minute control periods the perfusate was switched to one containing 1 mM AT-125 in addition to glutamine and after equilibration an additional 3 collections were obtained. Control period glutamine load averaged 16.1 +/- 2.4 pmole/min of which 35 percent was absorbed and 38 and 27 percent excreted as glutamine and glutamate respectively; of the absorbed glutamine 25 percent was metabolized. During AT-125 administration, glutamine delivery averaged 15.0 +/- 2.1 pmole/min of which 57 percent was absorbed; increased absorption occurred at the expence of intraluminal glutamate formation which fell to less than 10 percent. Thus luminal transport and gamma glutamyltransferase mediated hydrolysis appear to compete for available glutamine. Significantly, reducing intraluminal glutamine hydrolysis doubles the cellular metabolism of absorbed glutamine suggesting that extracellular conversion of glutamine to glutamate alters the metabolic fate of filtered glutamine.