Renal brush border glutamine transport: comparison between in situ and isolate membrane vesicle uptake

Regulation of expression of the SN1 transporter during renal adaptation to chronic metabolic acidosis in rats

During chronic metabolic acidosis, renal glutamine utilization increases markedly. We studied the expression of the system N1 (SN1) amino acid transporter in the kidney during chronic ammonium chloride acidosis in rats. Acidosis caused a 10-fold increase in whole kidney SN1 mRNA level and a 100-fold increase in the cortex. Acidosis increased Na(+)-dependent glutamine uptake into basolateral and brush-border membrane vesicles (BLMV and BBMV, respectively) isolated from rat cortex (BLMV, 219 +/- 66 control vs. 651 +/- 180 pmol. mg(-1). min(-1) acidosis; BBMV, 1,112 +/- 189 control vs. 1,652 +/- 148 pmol. mg(-1). min(-1) acidosis, both P < 0.05). Na(+)-independent uptake was unchanged by acidosis in BLMV and BBMV. The acidosis-induced increase in Na(+)-dependent glutamine uptake was eliminated by histidine, confirming transport by system N. SN1 protein was detected only in BLMV and BBMV from acidotic rats. After recovery from acidosis, SN1 mRNA and protein and Na(+)-dependent glutamine uptake activity rapidly returned to control levels. These data provide evidence that regulation of expression of the SN1 amino acid transporter is part of the renal homeostatic response to acid-base imbalance.

An Na(+)-dependent and an Na(+)-independent system for glutamine transport in rat liver basolateral membrane vesicles

In the present study the transport of glutamine across rat liver basolateral membrane was examined with special emphasis on the existence of an Na(+)-independent system and on the characteristics of the Na(+)-dependent system with respect to stoichiometry of glutamine to Na+. Well-validated and purified liver basolateral membrane vesicles were used in the study. Results of studies on the effect of incubation medium osmolarity and incubation temperature indicated that glutamine uptake by liver basolateral membrane vesicles is largely the result of transport of the substrate into the intravesicular compartment with little binding to basolateral membrane vesicles. Transport of glutamine with time was Na+ gradient dependent (out greater than in) with a distinct "overshoot" phenomenon. Replacing Na+ with an equivalent concentration of K+, NH4+, choline, or mannitol caused significant inhibition of the initial rate of glutamine transport; on the other hand, Li+ could partially substitute for Na+. The initial rate of transport of glutamine as a function of concentration (0.05-12 mmol/L) was saturable both in the presence and in the absence of an inwardly directed Na+ gradient. Apparent Km values of 2.95 and 3.35 mmol/L and Vmax values of 11,565 and 6663 pmol.mg protein-1.10s-1 were calculated in the presence and absence of a Na+ gradient, respectively. Both in the presence and absence of an Na+ gradient (out greater than in), transport of [3H]glutamine was significantly inhibited by the addition to the incubation medium of unlabeled glutamine as well as histidine, asparagine, and serine. Transport of glutamine by the Na(+)-dependent process was significantly inhibited or stimulated, respectively, by inducing a relatively positive or negative intravesicular space. On the other hand, glutamine transport by the Na(+)-independent process was not affected by changes in transmembrane electrical potential. Using the "activation method," the stoichiometry of glutamine Na+ transport was found to be 1:1. These results show that glutamine transport in rat liver basolateral membrane vesicles is carrier mediated both in the presence and absence of an Na+ gradient. Furthermore, the Na(+)-dependent process is electrogenic in nature (net positive) and cotransports one glutamine molecule with one Na+. Transport of glutamine by the Na(+)-independent system, on the other hand, is electroneutral in nature.

Glucocorticoid and acid-base homeostasis: effects on glutamine metabolism and transport

The amino acid glutamine serves as a major fuel, powering tubular transport processes and base generation in the kidneys of acidotic animals. Removing the adrenals limits the kidneys' response to an exogenous acid load and impairs the removal rate of glutamine from the blood. Administering glucocorticoid to adrenalectomized (ADX) rats reverses a small net release of glutamine to uptake; similarly, administering an exogenous acid load to ADX rats restores the kidneys to organs of net extraction. Glucocorticoid-induced uptake is substantially less than the filtered glutamine load in contrast to uptake across both the luminal and basolateral surfaces when filtered HCO3- is reduced. Furthermore, mitochondrial glutamine oxidation is glucocorticoid dependent with a distinct impairment exhibited by the ADX acidotic rat kidney. However, combining the effect of reduced filtered HCO3- with glucocorticoid supplementation results in a marked potentiation of glutamine uptake coupled to oxidation. These results are consistent with a proposed proximal tubule cell model in which basolateral glutamine uptake is inversely related to basolateral HCO3- efflux and coupled, in the presence of glucocorticoid, to mitochondrial oxidation. This model of glucocorticoid-induced ammoniagenesis predicts an increased renal work capacity when basolateral transport of a major metabolic fuel, glutamine, is closely coupled to its oxidative metabolism.

Sodium-coupled amino acid transport in renal tubule

Amino acids are reabsorbed from the tubular lumen by a saturable, carrier-mediated, concentrative transport mechanism driven by a Na+ electrochemical gradient across the luminal membrane. This process is followed by efflux mainly via carrier-mediated, Na+-independent facilitated diffusion across the basolateral membrane. Individual amino acids may have two or more Na+-dependent transport systems with different kinetic characteristics along the luminal membrane of the proximal tubule, thereby enabling very efficient amino acid reabsorption. Dual Na+-coupled transport pathways for some amino acids located in both the luminal and the peritubular membranes may operate in concert to provide the tubular epithelial cell with essential nutrients. One or more Na+ ions, H+, Cl- and in the case of acidic amino acids, K+ ion, may be involved in the translocation of the carrier complex. For most amino acids this process is electrogenic positive, favored by a negative cell interior. At least seven distinct, but largely interacting, Na+-dependent amino acid transport systems have been identified in the brush border membrane. A diet-induced adaptation in Na+-coupled taurine transport and acidosis-induced adaptive response in Na+-dependent glutamine transport are expressed at the luminal and the basolateral membrane surfaces, respectively. The aminoaciduria of early life may be related to a rapid dissipation of the Na+ electrochemical gradient necessary for amino acid reabsorption.

Transport of glutamine in rat intestinal brush-border membrane vesicles

Transport of glutamine across the brush-border membrane of the rat intestine was examined using brush-border membrane vesicle (BBMV) technique. Osmolarity and temperature studies indicated that the uptake of glutamine by BBMV is mostly the result of transport of the substrate into the intravesicular space. Transport of glutamine was Na+-gradient dependent (out greater than in) with a distinct 'overshoot' phenomenon. Initial rate of transport of glutamine as a function of concentration was saturable both in the presence and absence of a Na+ gradient (out greater than in). Apparent Km of 3.50 and 3.34 mM and Vmax of 707 and 282 pmol/mg protein per 7 s, were calculated for the Na+-dependent and the Na+-independent transport processes of glutamine. The transport of [3H]glutamine by the Na+-dependent and the Na+-independent processes was severely inhibited by the addition to the incubation medium of other amino acids and unlabelled glutamine. Inducing a relatively negative intravesicular compartment with the use of valinomycin and an outwardly directed K+ gradient stimulated glutamine transport. This indicates that transport of the substrate by the Na+-dependent process is electrogenic in nature. Transport of glutamine by the Na+-independent process, however, appeared to be electroneutral in nature. These results demonstrate the existence of two carrier-mediated transport processes for glutamine in the rat intestinal BBMV, one is Na+-dependent and the other is Na+-independent. Furthermore, the results suggest that glutamine transport by the Na+-dependent process probably occurs by a glutamine/Na+ cotransport mechanism.

Gamma glutamyltransferase contribution to renal ammoniagenesis in vivo

The role of gamma-glutamyltransferase (gamma-GT) in renal ammoniagenesis and glutamine utilization was evaluated in the intact functioning rat kidney. Total NH4+ released, as the sum of renal venous and urinary NH4+, was measured under conditions of chronic metabolic acidosis and paraminohippurate infusion. Ammonia derived from extracellular gamma-GT hydrolysis of glutamine was differentiated from that produced by intracellular phosphate dependent glutaminase (PDG) by employing acivicin, a gamma-GT inhibitor. In non-acidotic animals acivicin administration inhibited gamma-GT 95% and renal venous NH4+ release 48%; NH4+ release into the urine was not inhibited. Chronic metabolic acidosis elevated total NH4+ release 2.5fold, associated with adaptive increase in both gamma-GT and PDG; acivicin reduced total NH4+ released 36% with both renal venous and urinary release effected. The contribution of gamma-GT to total NH4+ production doubles in metabolic acidosis in agreement with the adaptive rise in the in vitro assayed gamma-GT activity. Luminal ammoniagenesis increases in chronic acidosis associated with a fall in urinary glutamine concentration and a rise in the blood to urine glutamine concentration gradient; gamma-GT inhibition eliminates this gradient suggesting luminal ammoniagenesis is largely dependent upon the paracellular glutamine flux. In support of this, paraminohippurate (PAH) infusion increased total renal NH4+ release due entirely to enhanced NH4+ excretion. PAH stimulated luminal ammoniagenesis was associated with an acceleration of renal glutamine extraction and a steeper blood to urine glutamine diffusion gradient; acivicin blocked this response consistent with PAH secretion coupled to activation of intraluminal gamma-GT and glutamine hydrolysis.