Amino acid reabsorption in the rat nephron. Free flow micropuncture study

Presaturation Power Adjusted Pulsed CEST: A Method to Increase Independence of Target CEST Signals

Chemical exchange saturation transfer (CEST) imaging has been demonstrated to discuss the concentration changes of amide proton, glutamate, creatine, or glucose measured at 3.5, 3.0, 2.0, and 1.0-1.2 ppm. However, these peaks in z-spectra are quite broad and overlap with each other, and thus, the independence of a CEST signal on any specific metabolite is still open to question. Here, we described whether there was interference among the CEST signals and how these CEST signals behave when the power of the presaturation pulse was changed. Based on these results, further experiments were designed to investigate a method to increase the independence of the CEST signal in both phantoms and animals. The result illustrates a clear interference among CEST signals. A presaturation power adjusted pulsed- (PPAP-) CEST method which was designed based on the exchange rates of the metabolites can be used to remove contributions from other exchanging species in the same sample. Further, the method was shown to improve the independence of the glutamate signal in vivo in the renal medulla in mice. The PPAP-CEST method has the potential to increase the independence of any target CEST signals in vivo by choosing the appropriate combination of pulse amplitudes and durations.

Increased L-arginine transport via system b0,+ in human proximal tubular cells exposed to albumin

Albumin has complex effects on PTECs (proximal tubular epithelial cells) and is able to stimulate growth or injury depending on its bound moieties. Albumin itself is a mitogen, inducing proliferation through a number of pathways. In PTEC exposed to purified albumin, polyamines are required for entry into the cell cycle and are critical for proliferation. Polyamines are synthesized from L-ornithine (itself derived by the action of arginase on L-arginine), and the transport and availability of L-arginine may thus be important for subsequent polyamine-dependent proliferation. In the present study we investigated radiolabelled cationic amino-acid transport in cultured PTEC exposed to 20 mg/ml ultrapure recombinant human albumin, describing the specific kinetic characteristics of transport and the expression of transporters. L-[3H]Arginine transport capacity in human PTEC is increased after exposure for 24 h to human albumin, mediated by the broad-scope high-affinity system b0,+ and, to a lesser extent, system y+L (but not system y+) transport. Increased transport is associated with increased b0,+-associated transporter expression. Inhibition of phosphoinositide 3-kinase, a key regulator of albumin endocytosis and signalling, inhibited proliferation, but had no effect on the observed increase in transport. PTEC proliferated in response to albumin. L-Lysine, a competitive inhibitor of L-arginine transport, had no effect on albumin-induced proliferation; however, arginine deprivation effectively reversed the albumin-induced proliferation observed. In conclusion, in PTEC exposed to albumin, increased L-arginine transport is mediated by increased transcription and activity of the apical b0,+ transport system. This may make L-arginine available as a substrate for the downstream synthesis of polyamines, but is not critical for cell proliferation.

Transepithelial transport and metabolism of glycine in S1, S2, and S3 cell types of the rabbit proximal tubule

In the first of two sets of experiments, the lumen-to-cell and cell-to-bath transport rates for glycine were measured in the isolated-perfused medullary pars recta (S3 cells) of the rabbit proximal tubule at multiple luminal glycine concentrations (0-2.0 mM). The lumen-to-cell transport of glycine was saturated, which permitted the calculation of the transport maximum of disappearance rate of glycine from the lumen (pmol.min(-1).mm tubular length(-1)), K(m) (mM), and paracellular leak (pmol.min(-1).mm tubular length(-1).mM(-1)) values for this transport mechanism; these values were 4.3, 0.3, and 0.03, respectively. The cell-to-bath transport did not saturate but showed a linear relationship to cellular glycine concentration, 0.58 pmol.min(-1).mm tubular length(-1).mM(-1). The second set of experiments characterized the transport rate, cellular accumulation, and metabolic rate of lumen-to-cell transported [(3)H]glycine in all segments (cell types) of the proximal tubule, pars convoluta (S1 cells), cortical pars recta (S2 cells), and medullary pars recta (S3 cells). These proximal tubular segments were isolated and perfused at a single glycine concentration of 11.2 microM. From the results of this study and previous work (Barfuss DW and Schafer JA. Am J Physiol 236: F149-F162, 1979), we conclude that the axial heterogeneity for glycine lumen-to-cell and cell-to-bath transport capacity extends to the medullary pars recta (S3 cells; S1 > S2 < S3 for lumen-to-cell transport and S1 > S2 > S3 for cell-to-bath transport). Also, we conclude that lumen-to-cell transported glycine can be metabolized and its metabolic rate displays axial heterogeneity (S1 > S2 > S3). The physiological significances of these transport and metabolic characteristics of the S3 cell type permits the medullary pars recta to effectively recover glycine from very low luminal glycine concentrations and makes glycine available for protective and maintenance metabolism of the medullary pars recta.

Two types of K(+) channels at the basolateral membrane of proximal tubule: inhibitory effect of taurine

The cell-attached configuration of the patch-clamp technique was used to investigate the effects of taurine on the basolateral potassium channels of rabbit proximal convoluted tubule. In the absence of taurine, the previously reported ATP-blockable channel, K(ATP), was observed in 51% of patches. It is characterized by an inwardly rectifying current-voltage curve with an inward slope conductance of 49 +/- 5 pS (n = 15) and an outward slope conductance of 13 +/- 6 pS (n = 15). The K(ATP) channel open probability (P(o)) is low, 0.15 +/- 0.06 (n = 15) at a -V(p) = -100 mV (V(p) is the pipette potential), and increases slightly with depolarization. The gating kinetics are characterized by one open time constant (tau(o) = 5.0 +/- 1.9 ms, n = 6) and two closed time constants (tau(C1) = 5. 2 +/- 1.5 ms, tau(C2) = 140 +/- 40 ms; n = 6). In 34% of patches, a second type of potassium channel, sK, with distinct properties was recorded. Its current-voltage curve is characterized by a sigmoidal shape, with an inward slope conductance of 12 +/- 2 pS (n = 4). Its P(o) is voltage independent and averages 0.67 +/- 0.03 (n = 4) at -V(p) = -80 mV. Both its open time and closed time distributions are described by a single time constant (tau(o) = 96 +/- 19 ms, tau(C) = 10.5 +/- 3.6 ms; n = 4). Extracellular perfusion of 40 mM taurine fails to affect sK channels, whereas K(ATP) channel P(o) decreases by 75% (from 0.17 +/- 0.06 to 0.04 +/- 0.02, n = 7, P < 0.05). In conclusion, the absolute basolateral potassium conductance of rabbit proximal tubules is the resulting combination of, at least, two types of potassium channels of roughly equal importance: a high-conductance low-open probability K(ATP) channel and a low-conductance high-open probability sK channel. The previously described decrease in the basolateral absolute potassium conductance by taurine is, however, mediated by a single type of K channel: the ATP-blockable K channel.

Cationic amino acid fluxes beyond the proximal convoluted tubule of rat kidney

To investigate the fluxes of cationic amino acids beyond the proximal convolution, we micropunctured and microperfused superficial tubules of male Wistar rats in vivo et situ. In free-flow micropuncture experiments, the concentrations of endogenous L-arginine+, [Arg], and of intravenously infused L-homoarginine+, [HoArg], were determined by HPLC. Fluorescein isothiocyanate-labeled inulin was detected on-line in the same tubular fluid samples. To determine undirectional fluxes, radiolabeled Arg and inulin were (1) microperfused through short loops of Henle and (2) microinfused into different tubule segments to measure urinary recovery of the radiolabel. At a mean [Arg]plasma of 116 mumol/l, [Arg] was 9.3 mumol/l in the late proximal tubule (LPT), and 35.6 mumol/l in the early distal tubule (EDT) corresponding to fractional deliveries (FD) of 0.055 in LPT and 0.078 in EDT. Fractional urinary excretion (FE) of Arg was 0.00033 (P < 0.05 vs FDEDT). Infusion of HoArg (2.5 or 7.5 mumol/min) led to respective mean [HoArg]plasma values of 1.44 and 3.73 mmol/l, and resulted in respective FDLPT values for HoArg of 0.23 and 0.53, respective FDEDT values of 0.29 and 0.41, and finally, respective FE values for HoArg of 0.25 and 0.58. When short loops of Henle were microperfused with 1 or 50 mmol/l [14C]Arg (+[3H]inulin), fractional recovery (FR) of 14C (relative to inulin) in the EDT was 0.13 and 0.36, respectively. During microinfusion of radiolabeled Arg (1 or 50 mmol/l) and inulin into LPT, the urinary FR of the radiolabel was 0.14, or 0.59, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Renal transport of taurine in luminal membrane vesicles from rabbit proximal tubule

The uptake of taurine by luminal membrane vesicles from pars convoluta and pars recta of rabbit proximal tubule was examined. In pars convoluta, the transport of taurine was characterized by two Na(+)-dependent (Km1 = 0.086 mM, Km2 = 5.41 mM) systems, and one Na(+)-independent (Km = 2.87 mM) system, which in the presence of an inwardly directed H(+)-gradient was able to drive the transport of taurine into these vesicles. By contrast, in luminal membrane vesicles from pars recta, the transport of taurine occurred via a dual transport system (Km1 = 0.012 mM, Km2 = 5.62 mM), which was strictly dependent on Na+. At acidic pH with or without a H(+)-gradient, the Na(+)-dependent flux of taurine was drastically reduced. In both kind of vesicles, competition experiments only showed inhibition of the Na(+)-dependent high-affinity taurine transporter in the presence of beta-alanine, whereas there was no significant inhibition with alpha-amino acids, indicating a beta-amino acid specific transport system. Addition of beta-alanine, L-alanine, L-proline and glycine, but not L-serine reduced the H(+)-dependent uptake of taurine to approx. 50%. Moreover, only the Na(+)-dependent high-affinity transport systems in both segments specifically required Cl-. Investigation of the stoichiometry indicated 1.8 Na+: 1 Cl-: 1 taurine (high affinity), 1 Na+: 1 taurine (low affinity) and 1 H+: 1 taurine in pars convoluta. In pars recta, the data showed 1.8 Na+: 1 Cl-: 1 taurine (high affinity) and 1 Na+: 1 taurine (low affinity).

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.

Taurine transport by rabbit kidney brush-border membranes: coupling to sodium, chloride, and the membrane potential

Ion dependence and electrogenicity of taurine uptake were studied in rabbit renal outer cortical brush-border membrane vesicles isolated by differential precipitation. Na+-D-glucose cotransport was followed in parallel to monitor changes in the membrane potential. Concentrative taurine flux was dependent on a chemical and/or an electrical Na+ gradient (K+ diffusion potential) and could be completely inhibited by other beta-amino acids. It displayed a specific anion requirement (Cl- greater than or equal to Br- much greater than SCN- greater than I- greater than NO-3). At chemical Na+ equilibrium, Cl- gradients, depending on their orientation, stimulated or inhibited taurine uptake more than could be attributed solely to electrical anion effects, although a Cl- gradient alone could not energize an overshoot. Furthermore, taurine tracer exchange was significantly stimulated by Cl- as well as Br-. The Cl- stoichiometry was found to be one, whereas taurine transport, in the presence of Cl-, was sigmoidally related to the Na+ concentration, resulting in a coupling ratio of 2 to 3 Na+: 1 taurine. Upon Cl- replacement with gluconate, taurine uptake showed a reduced potential sensitivity and was no longer detectably affected by the Na+ concentration (up to 150 mM). These results suggest a 2 to 3 Na+ :1 Cl- :1 taurine cotransport mechanism driven mainly by the Na+ gradient, which is sensitive to the membrane potential due to a negatively charged empty carrier. Cl- appears to stimulate taurine flux primarily by facilitating the formation of the translocated solute-carrier complex.

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.

The compartmentation of glycolytic and gluconeogenic enzymes in rat kidney and liver and its significance to renal and hepatic metabolism

An indirect immunoperoxidase procedure has been used to demonstrate sites of glycolysis and gluconeogenesis in normal rat kidney and liver. In kidney, the gluconeogenic enzyme fructose 1,6-biphosphatase was restricted to the proximal tubular epithelium, while the glycolytic enzyme hexokinase predominated in more distal segments. Intense staining for the biphosphatase in proximal convoluted tubular brush borders suggests that reabsorbed substrates may be used directly at this site in renal gluconeogenesis. In view of the high phosphofructokinase and pyruvate kinase activities present in collecting ducts, their relatively low hexokinase activities and their relatively pale immunostaining for hexokinase indicate that glycolytic substrates which feed into the pathway subsequent to the initial phosphorylation step, rather than glucose, may be the major energy source for the rat renal papilla. Immunostaining in the liver was consistent with the metabolic zonation of liver parenchyma, in that glucokinase occurred mainly in perivenous regions and fructose 1,6-bisphosphatase in periportal areas. The presence of such metabolic zonation is difficult to reconcile with the widely held view that the majority of hepatic glycogen is derived directly from glucose. A model for hepatic glycogen synthesis is proposed which links the concept of parenchymal zonal heterogeneity with recent biochemical evidence concerning the 'glucose paradox' and with microscopical studies on the dynamics of glycogen deposition after refeeding.

Contribution of individual superficial nephron segments to ammonium handling in chronic metabolic acidosis in the rat. Evidence for ammonia disequilibrium in the renal cortex

Ammonia entry along surface nephron segments of rats was studied with micropuncture techniques under control and chronic metabolic acidosis conditions. Tubule fluid was collected successively from sites at the end and beginning of the distal tubule and at the end of the proximal tubule of the same nephron. During chronic metabolic acidosis, ammonium excretion doubled. As anticipated, the ammonium concentration (TFNH+4) was significantly higher in proximal tubule fluid during acidosis, and ammonium delivery to end proximal sites increased from 19.4 +/- 2.3 to 34.0 +/- 3.2 pmol/min (P less than 0.001). Although chronic acidosis did not affect TFNH+4 at the beginning of the distal tubule, ammonium delivery to the end of the distal tubule increased from 5.72 +/- 0.97 to 9.88 +/- 0.97 pmol/min. In both control and acidotic groups ammonium delivery was lower (P less than 0.001) to end distal sites than to end proximal sites, indicating net loss in the intervening segment. This loss was greater during chronic metabolic acidosis (23.9 +/- 3.3 vs. 13.6 +/- 2.0 pmol/min in controls, P less than 0.025). In both groups net entry of ammonia, in similar amounts, occurred along the distal tubule (P less than 0.05). In situ pH averaged 6.80 +/- 0.05 at end proximal tubule sites and fell to 6.54 +/- 0.08 at the beginning of the distal tubule (P less than 0.005). Chronic metabolic acidosis did not affect these measurements. The calculated free ammonia at the end of the proximal tubule rose from 9.3 +/- 2.2 to 21 +/- 9 microM (P less than 0.005) during chronic metabolic acidosis, and was also higher at beginning distal sites during acidosis (8.8 +/- 2.4 vs. 2.7 +/- 0.7 microM in controls, P less than 0.05). In both groups ammonia values for the beginning distal tubule fluid were lower than for end proximal tubule fluid. Thus, loss of ammonium in the loop segment is enhanced by chronic metabolic acidosis. Distal entry of ammonia is markedly less than along the proximal tubule and does not change in chronic metabolic acidosis, and ammonia permeabilities for the proximal and distal segments of surface nephrons seem different.

Molecular specificity of the tubular resorption of "acidic" amino acids. A continuous microperfusion study in rat kidney in vivo

Single sections of superficial proximal convolutions of rat kidney were microperfused in vivo and in situ. The perfusion fluids contained radioactively labelled L- or D-aspartate, L-glutamate, L-pyroglutamate, or N-methyl-D-aspartate. L-gamma-Carboxyglutamate as well as the other amino acids were added in the unlabelled form. Results. L- and D-Aspartate (0.073 mmol X 1(-1)) are quickly resorbed at about the same rate. D-Aspartate resorption was blocked by L-aspartate (5 mmol X 1(-1)) but not by beta-alanine (5 mmol X 1(-1)). L-Aspartate resorption was inhibited by L-glutamate (2 mmol X 1(-1)) but not by D-glutamate, L-asparagine, L-phenylalanine or by succinate (2 mmol X 1(-1), each). The fast resorption of L-glutamate (0.073 mmol X 1(-1)) was blocked by D-aspartate, L-cysteate (2 mmol X 1(-1)), but not by 3-mercaptopicolinic acid (0.15 mmol X 1(-1)), L-glutamine, 2-oxoglutarate, taurine, N-methyl-L-glutamate or kainic acid (2 mmol X 1(-1), each). L-gamma-Carboxyglutamate (0.66 mmol X 1(-1)) and N-methyl-D-aspartate (2 mumol X 1(-1)) were found to be resorbed only at an extremely small rate. L-Pyroglutamate (0.076 mmol X 1(-1)) resorption was not influenced by L-glutamate (1 mmol X 1(-1)). Fractional excretion of gamma-carboxyglutamate was 7-25% (L-form) or 45-70% (D-form) at an artificially elevated plasma level of 12 mumol X 1(-1). It is concluded that L- and D-aspartate, L-glutamate, L-cysteate and, to a much smaller extent, L-gamma-carboxyglutamate, are accepted by the tubular resorption mechanism highly specific for "acidic" amino acids. N-Substitution, the amidation of the beta- or gamma-carboxyl group, or the removal of the alpha-amino moiety almost completely abolish the ability of such compounds to be resorbed via this carrier; N-methylated or gamma-carboxylated derivatives of "acidic" amino acids are not resorbed at all from the proximal tubule. The resorption of glutamate, but not of aspartate, is highly stereospecific.

Kinetics and localization of tubular resorption of "acidic" amino acids. A microperfusion and free flow micropuncture study in rat kidney

The unidirectional resorption rates of L-glutamate (initial concentrations of 0.07, 0.66, 2.0 or 20.0 mmol X 1(-1)), D-glutamate (0.66 mmol X 1(-1) in the presence or absence of 20 mmol X 1(-1) L-glutamate), and of L-aspartate (0.073, 0.3, 0.66, 2.0 or 5.0 mmol X 1(-1)) were determined in the rat proximal convolution. L-Glutamate resorption was saturable. A permeability coefficient (P) of less than or equal to 20 microns2 X S-1, and a maximum resorption rate (Jmax) of 0.15 +/- 0.015 (SEM) nmol X S-1 X m-1 at a Km of 0.17 +/- 0.025 (SEM) mmol X 1(-1) was obtained for L-glutamate. For L-aspartate, Jmax was 0.13 +/- 0.005 at a Km of 0.1 +/- 0.013. A free flow glutamate concentration profile along the proximal convolution was (I) predicted from these constants and (II) actually measured by means of free flow micropuncture. The data agree very well and show that more than 90% of the filtered load is resorbed within the first third of the proximal convolution. The late proximal and early distal free flow recoveries of L-glutamate amounted to 5.3 +/- 1.7% (SEM) and 6.6 +/- 1.4% of the filtered load, respectively. In contrast to this, unidirectional resorption during the microperfusion of the same tubule section was high: fractional resorption amounted to ca. 96% at 2 mmol X 1(-1) initial L-glutamate. It fell to 35 or 33% respectively if the initial L-glutamate concentration was 20 mmol X 1(-1) or if the resorption of 0.66 mmol X 1(-1) D-glutamate in presence of 20 mmol X 1(-1) L-glutamate was measured. The fractional excretion of endogenous L-glutamate in the final urine amounted to 0.13 +/- 0.012% of the filtered load. It is concluded that L-glutamate and L-aspartate are quickly resorbed in early parts of the proximal convolution (low Km). Saturation already occurs when there is a small increase in the filtered load (low Jmax). The nephron section between the late proximal and early distal nephron sites also reabsorbs "acidic" amino acids. Normally, however, the back leak cancels this out, and net flux becomes zero. Deep nephrons seem to handle amino acids somewhat differently than superficial nephrons do.

Taurine transport by isolated flounder renal tubules

Previous in vivo clearance studies (Schrock et al., '82) have revealed that taurine is secreted by marine fish kidneys. In the present study taurine secretion by the flounder (Pseudopleuronectes americanus) renal tubule was investigated by assaying the transport of 14C-taurine in vitro. Collections from isolated fluid-secreting flounder tubules confirmed the presence of a tubular mechanism for taurine secretion. The flounder renal tubule concentrated taurine in the lumen at a lumen/bath ratio of 25, with the movement across the peritubular membrane identified as the concentrating step of taurine transport. Studies with teased flounder renal tubules identified transport as Na+ and C1- dependent. Taurine transport was inhibited by beta alanine, gamma-aminobutyric acid, and hypotaurine. In a study of the hormonal control of taurine transport, only the adrenal steroid dexamethasone stimulated taurine uptake by the flounder renal tubules. Transport was not affected by the second messengers adenosine 3'5'-cyclic monophosphate, guanosine 3'5'-cyclic monophosphate, adenosine, or Ca++ ionophore (A12384).

Electrophysiological analysis of rat renal sugar and amino acid transport. IV. Basic amino acids

Electrophysiological techniques were used to study the transport of the basic amino acids L-arginine, L-lysine and L-ornithine in rat kidney proximal tubule in vivo. Tubular cells were punctured with microelectrodes and the response of the cell membrane potential to sudden applications of the amino acids was measured. In the presence of physiological Na+ concentrations luminal perfusion with millimolar concentrations of basic amino acids depolarized the tubular cells in a concentration dependent fashion by up to 15 mV, while in the absence of Na+ no significant potential changes were observed. These observations indicate that the basic amino acids are taken up into the cell across the brushborder in coupling with Na+ ions in a similar way as neutral and acidic amino acids, and that simple conductive pathways for uncoupled flow of the basic amino acids do either not exist or are quantitatively negligible in the brushborder. From kinetic measurements and competition experiments it was concluded that all basic amino acids are transported by the same transport system, which however does not accept acidic or neutral amino acids (with the possible exception of L-cystine). Perfusion of the peritubular capillaries with millimolar concentrations of basic amino acids depolarized the cells only by approximately 1 mV, both in the presence and absence of Na+. This observation may indicate that a passive uncoupled transport pathway for basic amino acids is present in the peritubular cell membrane to allow exit from cell to interstitial space, if the intracellular concentration rises high enough to overcome the cell membrane potential.

Electrophysiological analysis of rat renal sugar and amino acid transport. V. Acidic amino acids

We have used electrophysiological techniques to study various aspects of the transport of glutamate and aspartate in proximal tubules of the rat kidney in vivo. Single tubular cells were punctured with microelectrodes and the response of the cell membrane potential to sudden luminal or peritubular applications of these amino acids was measured. The experiments indicated that a specific transport system exists for L-glutamate and L-aspartate in the brushborder membrane, which does not transport neutral or basic amino acids. The uptake of both L-amino acids from the lumen into the cell was found to be rheogenic, probably reflecting the cotransport of two Na+ ions together with one amino acid molecule. The transport system has a slightly greater affinity for L-glutamate, but transports the smaller L-aspartate somewhat faster. Besides the L-isomers also D-glutamate and D-aspartate were found to depolarize the tubular cells which suggests that also the D-isomers are absorbed in the tubule, however they do not seem to use the same transport system as the L-isomers. In addition to the transport system in the brushborder, a similar Na+-dependent, rheogenic transport system for L-glutamate and L-aspartate was also found in the peritubular cell membrane, as deduced from cell cell depolarizations in response to these substrates applied peritubularly. The simultaneous presence of Na-driven transport systems in the apical and basal cell membrane which is not found with other amino acids, may explain the high intracellular accumulation of L-glutamate and L-aspartate in the kidney and provides a rational basis for explaining clinically observed cases of dicarboxylic aminoacidurias.

Proline and glucose transport by renal membranes from dogs with spontaneous idiopathic Fanconi syndrome

The uptake of proline and glucose by renal brush border membrane vesicles isolated from Basenji dogs exhibiting a spontaneous Fanconi syndrome was examined. The magnitude of the 1-min, Na+-gradient uptake of proline (0.02 mM) and glucose (1.0 mM) by vesicles from affected dog kidney was lower than normal. Concentration-dependent 15-sec uptake in vesicles from normal and affected dogs reveals a two-component transport system for proline and glucose. Kinetic analysis shows altered Km and Vmax values for both proline and glucose transport in the affected dogs. The data suggest that, in this model of Fanconi syndrome, the defective renal reabsorption of proline and glucose is associated with an alteration of luminal transport system.

Kinetics of L-proline reabsorption in rat kidney studied by continuous microperfusion

Renal tubular reabsorption of 3H and 14C labelled L-proline was measured in vivo et situ by continuous microperfusion of single proximal tubules of the rat. The reabsorption is shown to be saturable. Passive diffusion plays a relatively small role in the reabsorption. A maximum possible permeability coefficient of 25 micrometers 2.s-1 for proline was calculated. Two transport systems were found, one with a small affinity and a high capacity, the other with a very high affinity and a small capacity. The following values were estimated. Jmax 1 = 2.6 +/- 0.28 (SEM) nmol.m-1.S-1 Km1 = 11.8 +/- 1.7 (SEM) mmol.1-1 Jmax 2 = 9.6 +/- 1.92 (SEM) pmol.m-1.s-1 Km2 = 29.3 +/- 7.8 (SEM) mumol.1-1. Whereas the first system reabsorbs the bulk of the filtered load, the activity of the second system explains the extremely small amount of proline found in the final urine. Diisopropylphosphorofluoridate--a specific inhibitor of dipeptidyl peptidase IV--decreases the reabsorption of L-proline and L-alanine but has no influence on the reabsorption of the basic amino acid L-arginine and the acidic amino acid L-glutamic acid. This result correlates with a recent speculation that dipeptidyl peptidase IV is involved in proline and alanine reabosrption.

Maleic acid induced aminoaciduria, studied by free flow micropuncture and continuous microperfusion

The injection of 200 mg/kg BW maleic acid was found to be a suitable dose for exploring the experimental Fanconi syndrome by micropuncture techniques in rats. In clearance experiments, the fractional excretion of glycine, L-alanine, L-aspartate and taurine was measured. After intraperitoneal administration of maleic acid the excretion of these amino acids was increased in the range between the 20-fold and the 230-fold. Free flow micropuncture experiments showed that the reabsorption of these amino acids is reduced drastically along the whole proximal tubule. Continuous microperfusion experiments lead to the result that, in maleic acid pretreated rats, the reabsorption of 14C-glycine from the proximal convolution was strongly inhibited. It was found, furthermore, that after blocking the saturable glycine transport by L-phenylalanine, the remaining reabsorption of glycine (corresponding to passive diffusion) was exactly the same with and without maleic acid. Microinfusion experiments with 8 mumol.1(-1) L-3H-alanine into the early distal tubule showed a fractional recovery of 103 +/- 4.2% (S.D.) in the control and of 101 +/- 6.5% in presence of maleic acid. It is concluded that maleic acid inhibits the saturable reabsorption mechanism of amino acids along the proximal tubule. Passive permeability of the tubular membrane does not seem to be altered by maleic acid.

Renal transport of amino acids

According to recent experimental data the renal transport of amino acids (AA) is characterized as follows. 1. Kinetics: Several reabsorption systems remove AA from the tubular fluid by active transport with Michaelis-Menten type kinetics. Passive diffusion does play only a relatively small role in reabsorption, but determines the pump leak steady state concentration at the end of the tubule. 2. Stereospecificity: Except for aspartate the naturally occurring L-analogs show a much larger affinity to the transport "carriers" than the D-isomers do. 3. Specificity: Separate transport mechanisms exist for a) the "acidic" AA (Glu and Asp); b) the "dibasic" AA (Arg, Lys, Orn); c) cystine/cystine; d) the "imino" acids (Pro, OH-Pro and other N-substituted AA); e) the beta- and gamma-AA (beta-Ala, GABA, Taurine); f) all other "neutral" AA. For the group (d) and maybe also for (b) and glycine additional low capacity/high affinity systems exist. 4. Localization: Except for glycine and taurine under normal conditions more than 80% of the filtered load are reabsorbed within the first third of the proximal tubule. At an elevated load the rest of the proximal tubule (including pars recta) but not the distal nephron is included into the reabsorptive process. AA are also taken up from the peritubular blood. 5. Energy sources: At least the main part of AA uptake at the brushborder membrane is dependent from a transmembranal Na+-gradient which in turn is established by the ATP driven Na+-pumps at the basolateral side of the cell (Secondary active transport or co-transport of AA). 6. Biochemistry: The biochemical nature of the AA-"carriers" is unknown. The recent hypothesis than a "gamma-glutamyl cycle" plays a major role in this context has been disproved to great extent. 7. Peptides: Oligopeptides (Angiotensin, Gluthathion) filtered at the glomerulum are hydrolyzed by brushborder peptidases within the tubule lumen. The splitting products, the free constituent amino acids, are reabsorbed subsequently by their respective transport systems.

Micropuncture studies of the transport of individual amino acids by the Necturus proximal tubule

Absorption of amino acids by the necturus proximal tubules was measured under free-flow conditions The coexistence of proximal tubular amino acid influx was determined by infusing saline into tubular lumens by the stopped-flow microperfusion technique. Under free-flow conditions, fractional absorption of individual amino acids ranged from 0.30 +/- 0.18 (glutamic acid) to 0.96 +/- 0.02 (proline), with 14 of 19 values greater than 0.75. The transport avidity for a given amino acid bore no relationship to its molecular weight, transport class, or plasma concentration. The values obtained for tubular fluid/plasma (TF/P) were very comparable to those reported for the rat. In stopped-flow microperfusion experiments, samples of isotonic saline residing in tubule lumens for 20 min were found to contain all the amino acids present in plasma (filtrate). The concentrations of all except the acidic anionic pair, glutamic acid and aspartic acid, were remarkably similar to those obtained by collection of end proximal samples in free-flow studies. The very high concentrations of the acidic amino acids may reflect their passive distribution across the luminal cell membrane, active absorption having been impaired by the absence of some substance normally present in glomerular filtrate.

Renal tubular reabsorption of taurine, gamma-aminobutyric acid (GABA) and beta-alanine studied by continuous microperfusion

Renal tubular reabsorption of taurine, gamma-aminobutyric acid (GABA), and beta-alanine was studied in vivo et situ by continuous microperfusion of single proximal tubules of the rat. In each case, reabsorption was much slower than that for other amino acids that have been studied. With a concentration of 0.1 mmol/l in initial load was reabsorbed over perfusion distance of 3 mm. Taurine reabsorption saturated with only 2.17 mmol/l in initial perfusate. Assuming simple two-parameter kinetics, upper limits for Km of 0.54 mmol/l and forVmax of 0.59 pmol-cm-1--s-1 for tubular reabsorption of taurine were estimated. High (20 mmol/l) concentrations of taurine or beta-alanine in perfusate completely inhibited GABA reabsorption, but L-phenylalanine (20 mmol/l) had no significant effect. The results indicate that the three amino acids are reabsorbed slowly from the proximal tubule by what may be a common transport system. This system appears to have a high affinity but low capacity and to be different from other known renal tubular transport systems for amino acids.

Mechanism of NaCl and water reabsorption in the proximal convoluted tubule of rat kidney

The role of chloride concentration gradients in proximal NaCl and water reabsorption was examined in superficial proximal tubules of the rat by using perfusion and collection techniques. Reabsorptive rates (Jv), chloride concentrations, and transtubular potential difference were measured during perfusion with solutions (A) simulating an ultrafiltrate of plasma; (B) similar to (A) except that 20 meq/liter bicarbonate was replaced with acetate; (C) resembling late proximal fluid (glucose, amino acid, acetate-free, low bicarbonate, and high chloride); and (D) in which glucose and amino acids were replaced with raffinose and bicarbonate was partially replaced by poorly reabsorbable anions (cyclamate,sulfate, and methyl sulfate). In tubules perfused with solutions A and B, Jv were 2.17 and 2.7 nl mm-1 min-1 and chloride concentrations were 131.5 +/- 3.1 and 135 +/- 395 meq/liter, respectively, indicating that reabsorption is qualitatively similar to free-flow conditions and that acetate adequately replaces bicarbonate. With solution C, Jv was 2.10 nl mm-1 min-1 and potential difference was +1.5 +/- 0.2 mV, indicating that the combined presence of glucose, alanine, acetate, and bicarbonate per se is not an absolute requirement. Fluid reabsorption was virtually abolished when tubules were perfused with D solutions; Jv was not significantly different from zero despite sodium and chloride concentrations similar to plasma; chloride concentration was 110.8 +/- 0.2 meq/liter and potential difference was -0.98 mV indicating that chloride was close to electrochemical equilibrium. These results suggest the importance of the chloride gradient to proximal tubule reabsorption in regions where actively reabsorbable solutes (glucose, alanine, acetate, and bicarbonate) are lacking and provide further evidence for a passive model of NaCl and water transport.

Microperfusion study of the kinetics of reabsorption of cycloleucine in early and late segments of the proximal convolution of the rat nephron

The proximal tubular reabsorptive capacity for the non-metabolizable amino acid, cycloleucine, was studied in the rat nephron by stationary microperfusion. Tubular reabsorptive rates were greatest near the glomerulus and declined progressively along the convolution. A kinetic analysis of cycloleucine reabsorption in terms of luminal concentration revealed that this reduced transport rate was associated with an increase in the half-saturation constant of the kinetic curve, rather than a decrease in the maximum transport capacity. Since our previous findings with the metabolizable amino acid, -L-histidine, were identical we can conclude that this decline in reabsorption of neutral amino acids as a function of distance along the convolution is an intrinsic property of the transport system and is not related to tubule cell amino acid metabolism. The transport curves for cycloleucine absorption did not give a simple Michaelis-Menten relation but rather followed a course suggesting that more than one transport system might be involved.