Electrophysiological analysis of rat renal sugar and amino acid transport

Quantifying the relative contributions of different solute carriers to aggregate substrate transport

Determining the contributions of different transporter species to overall cellular transport is fundamental for understanding the physiological regulation of solutes. We calculated the relative activities of Solute Carrier (SLC) transporters using the Michaelis-Menten equation and global fitting to estimate the normalized maximum transport rate for each transporter (V_max). Data input were the normalized measured uptake of the essential neutral amino acid (AA) L-leucine (Leu) from concentration-dependence assays performed using Xenopus laevis oocytes. Our methodology was verified by calculating Leu and L-phenylalanine (Phe) data in the presence of competitive substrates and/or inhibitors. Among 9 potentially expressed endogenous X. laevis oocyte Leu transporter species, activities of only the uniporters SLC43A2/LAT4 (and/or SLC43A1/LAT3) and the sodium symporter SLC6A19/B⁰AT1 were required to account for total uptake. Furthermore, Leu and Phe uptake by heterologously expressed human SLC6A14/ATB^0,+ and SLC43A2/LAT4 was accurately calculated. This versatile systems biology approach is useful for analyses where the kinetics of each active protein species can be represented by the Hill equation. Furthermore, its applicable even in the absence of protein expression data. It could potentially be applied, for example, to quantify drug transporter activities in target cells to improve specificity.

Amino acid transport across mammalian intestinal and renal epithelia

The transport of amino acids in kidney and intestine is critical for the supply of amino acids to all tissues and the homeostasis of plasma amino acid levels. This is illustrated by a number of inherited disorders affecting amino acid transport in epithelial cells, such as cystinuria, lysinuric protein intolerance, Hartnup disorder, iminoglycinuria, dicarboxylic aminoaciduria, and some other less well-described disturbances of amino acid transport. The identification of most epithelial amino acid transporters over the past 15 years allows the definition of these disorders at the molecular level and provides a clear picture of the functional cooperation between transporters in the apical and basolateral membranes of mammalian epithelial cells. Transport of amino acids across the apical membrane not only makes use of sodium-dependent symporters, but also uses the proton-motive force and the gradient of other amino acids to efficiently absorb amino acids from the lumen. In the basolateral membrane, antiporters cooperate with facilitators to release amino acids without depleting cells of valuable nutrients. With very few exceptions, individual amino acids are transported by more than one transporter, providing backup capacity for absorption in the case of mutational inactivation of a transport system.

Absence of KCNQ1-dependent K+ fluxes in proximal tubular cells of frog kidney

The present study was designed to investigate the functional significance of KCNQ1-mediated K+ secretory fluxes in proximal tubular cells of the frog kidney. To this end, we investigated the effects on rapid depolarization and slow repolarization of the peritubular membrane potential after luminal addition of L-phenylalanine or L-alanine plus/minus KCNQ1 channel blockers. Perfusing the lumen with 10 mmol/L L-phenylalanine plus/minus luminal 293B, a specific blocker of KCNQ1, did not modify the rapid depolarization and the rate of slow repolarization. Perfusing the lumen with 10 mmol/L L-alanine plus/minus luminal HMR-1556, a more potent KCNQ1 channel blocker, did not also alter the rapid depolarization and the rate of slow repolarization. Pretreatment (1 h) of the lumen with HMR-1556 also failed to modify rapid depolarization and rate of slow repolarization upon luminal 10 mmol/L L-alanine. Perfusing the lumen with 1 mmol/L L-alanine plus/minus luminal HMR-1556 did not change the rapid depolarization and the rate of slow repolarization. The pretreatment (1 h) with luminal HMR-1556 did not modify the rapid depolarization and the rate of slow repolarization upon luminal 1 mmol/L L-alanine. The pretreatment (1 h) of the lumen with HMR-1556 did not change transference number for K+ of peritubular cell membrane. Finally, luminal barium blunted the rapid depolarization upon application of luminal 1 mmol/L L-alanine. RT-PCR showed that KCNQ1 mRNA was not expressed in frog kidney. In conclusion, the KCNQ1-dependent K+ secretory fluxes are absent in proximal tubule of frog kidney.

Amino acid transport in podocytes

It has recently been shown that formation of podocyte foot processes is dependent on a constant source of lipids and proteins (Simons M, Saffrich R, Reiser J, and Mundel P. J Am Soc Nephrol 10: 1633-1639, 1999). Here we characterize amino acid transport mechanisms in differentiated cultured podocytes and investigate whether it may be disturbed during podocyte injury. RT-PCR studies detected mRNA for transporters of neutral amino acids (ASCT1, ASCT2, and B(0/+)), cationic AA (CAT1 and CAT3), and anionic AA (EAAT2 and EAAT3). Alanine (Ala), asparagine, cysteine (Cys), glutamine (Gln), glycine (Gly), leucine (Leu), methionine (Met), phenylalanine (Phe), proline (Pro), serine (Ser), threonine (Thr), glutamic acid (Glu), arginine (Arg), and histidine (His) depolarized podocytes and increased their whole cell conductances. Depletion of extracellular Na(+) completely inhibited the depolarization induced by Ala, Gln, Glu, Gly, Leu, and Pro and decreased the depolarization induced by Arg and His, indicating the presence of Na(+)-dependent amino acid transport. Incubation of podocytes with 100 microg/ml puromycin aminonucleoside for 24 h significantly attenuated the effects induced by the various amino acids by approximately 70%. The data indicate the existence of different amino acid transporter systems in podocytes. Alteration of amino acid transport may participate in podocyte injury and disturbed foot process formation.

Altered membrane ionic permeability in a rat model of chronic renal failure

Acute elevations in intracellular adenosine 3',5'-cyclic monophosphate (cAMP) concentrations are known to increase ionic chloride permeability in diverse tissues. To determine if chronic endogenous increases in cAMP are associated with sustained alterations in membrane ionic permeabilities, renal cortical brush border membrane vesicles (BBMV) were prepared and red blood cells were harvested in a model of chronic renal failure, the 75% nephrectomized rat. Relative ionic permeabilities were determined using the potential-sensitive fluorescent probe 3,3'-dipropylthiadicarbocyanine iodide [diS-C3-(5)]. These studies demonstrate that renal cortical homogenate and RBC cAMP concentrations are increased in chronic renal failure animals. In the same animals relative ionic chloride permeability (PCl/PK) was significantly increased in renal cortical BBMV and RBC ghosts: PNa/PK was not affected. This selective change in permeability results in a significant increase in PCl/PNa and hyperpolarization of BBMV of sufficient magnitude to stimulate Na(+)-dependent glutamine transport. The change in glutamine uptake was not consequent to an alteration in the kinetics of glutamine transport or delayed dissipation of the inward Na+ gradient. Renal hypertrophy per se did not effect renal homogenate cAMP concentration or relative ionic permeability of renal cortical BBMV prepared from kidneys of uninephrectomized animals fed a 40% protein diet. These studies demonstrate that relative ionic chloride permeability and tissue [cAMP] are chronically increased in diverse cells (renal proximal tubule and RBCs) in a rat model of renal failure. These findings suggest that membrane ionic permeability may be altered and electrogenic transport secondarily perturbed in renal failure in association with hormonally-induced chronic elevations of intracellular cAMP concentrations.

Transport of cationic amino acids by the mouse ecotropic retrovirus receptor

Susceptibility of rodent cells to infection by ecotropic murine leukaemia viruses (MuLV) is determined by binding of the virus envelope to a membrane receptor that has multiple membrane-spanning domains. Cells infected by ecotropic MuLV synthesize envelope protein, gp70, which binds to this receptor, thereby preventing additional infections. The consequences of envelope-MuLV receptor binding for the infected host cell have not been directly determined, partly because the cellular function of the MuLV receptor protein is unknown. Here we report a coincidence in the positions of the first eight putative membrane-spanning domains found in the virus receptor and in two related proteins, the arginine and histidine permeases of Saccharomyces cerevisiae (Fig. 1), but not in any other proteins identified by computer-based sequence comparison of the GenBank data base. Xenopus oocytes injected with receptor-encoding messenger RNA show increased uptake of L-arginine, L-lysine and L-ornithine. The transport properties and the expression pattern of the virus receptor behave in ways previously attributed to y+, the principal transporter of cationic L-amino acids in mammalian cells.

Effect of prostaglandin E2 on proline uptake and protein synthesis by cultured human mesangial cells

PGE2 production by glomeruli is increased in a variety of glomerular diseases. Potentially, this process may affect mesangial cell protein synthesis and mesangial cell growth. Thus studies have been undertaken, using cultured human mesangial cells, to assess the effects of PGE2 on proline uptake, protein synthesis and cell proliferation. In the presence of 140 mM NaCl, incubation of mesangial cells with 0.01 to 1 microM PGE2 for 72 hours resulted in a marked decrease of 14C proline uptake, but did not modify 14C leucine uptake. Substitution of choline to sodium inhibited 14C proline uptake by 85% which became independent of PGE2, indicating that this PG specifically altered sodium-dependent proline uptake. Inhibition of this component reached 35 to 50% with 1 microM PGE2. The inhibitory effect of PGE2 on sodium-dependent proline uptake required a lag time of 48 hours, and was suppressed by ouabain, an inhibitor of Na+, K+ ATPase activity. PGE2 did not modify the Vmax of the transport system (1.007 vs. 1.023 nmol/mg/min) but increased (P less than 0.01) its Km (1.179 vs. 0.823 mM). 8-bromo-cyclic AMP also inhibited sodium-independent proline uptake, and PGE2 markedly increased cyclic AMP production. Taken together, these results suggested that PGE2 acted via cyclic AMP stimulation. PGE2 under identical conditions (1 microM, 72 hr incubation) produced a decrease in collagen synthesis estimated by the relative rate of collagen production after incubation of mesangial cells with 14C proline (percentage of 14C radioactivity in collagenase-sensitive proteins over total proteins). PGE2 also diminished the intracellular free proline pool. More generally, PGE2 inhibited cell proliferation and cell total proteins.(ABSTRACT TRUNCATED AT 250 WORDS)

Mutual inhibition of sugars and amino acid intestinal absorption

1. Intestinal absorption of sugars shows interaction with amino acids and vice versa. 2. The percentage of inhibition induced by a substrate depends on the type of substrate and the substance affected. 3. The mutual inhibition of monosaccharides and amino acids can be explained by five different hypotheses. 4. The most accepted hypotheses are the "allosteric interaction" and the "accelerated efflux". 5. From the results in the literature it is difficult to decide which of the two hypotheses is the more accurate.

Electrophysiological investigation of the amino acid carrier selectivity in epithelial cells from Xenopus embryo

The electrical responses induced by external applications of neutral amino acids were used to determine whether different carriers are expressed in the membrane of embryonic epithelial cells of Xenopus laevis. Competition experiments were performed under voltage-clamp conditions at constant membrane potential. Gly, L-Ala, L-Pro, L-Ser, L-Asn and L-Gln generate electrical responses with similar apparent kinetic constants and compete for the same carrier.They are [Na]o and voltage-dependent, insensitive to variations in [Cl]o and [HCO3]o, inhibited by pHo changes, by amiloride and, for a large fraction of the current, by MeAIB. The increase in [K]o at constant and negative membrane potential reduces the response, whereas lowering [K]o augments it. L-Leu, L-Phe and L-Pro appear to compete for another carrier. They generate electrogenic responses insensitive to amiloride and MeAIB, as well as to alterations of membrane potential, [Na]o and [K]o. Lowering [Cl]o decreases their size, whereas increasing [HCO3]o at neutral pHo increases it. It is concluded that at least two and possibly three transport systems (A, ASC and L) are expressed in the membrane of the embryonic cells studied. An unexpected electrogenic character of the L system is revealed by the present study and seems to be indirectly linked to the transport function. L-Pro seems to be transported by system A or ASC in the presence of Na and by system L in the absence of Na. MeAIB induces an inward current.

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.

Electrogenic transport of neutral and dibasic amino acids in a cultured opossum kidney cell line (OK)

A study has been made of electrogenic cellular uptake of amino acids resulting in the depolarization of cell membrane potential (PDm) in confluent monolayers of an established opossum kidney (OK) cell line using conventional and pH-selective microelectrodes. Apical superfusion of neutral and dibasic amino acids rapidly depolarized the cell membrane, while application of acidic amino acids had no effect on PDm. The depolarization in response to L-phenylalanine and L-arginine was stereoselective, dose-dependent and saturable. 10 mmol/l of L-phenylalanine reduced PDm by 4.8 +/- 0.4 mV (n = 51) in a completely sodium-dependent way and the concentration necessary for half-maximal depolarization (C1/2) was about 1.5 mmol/l. On the other hand, the C1/2 for L-arginine was about 0.02 mmol/l. The maximal depolarization produced by L-arginine (measured at 10 mmol/l) amounted to 6.8 +/- 1.2 mV (n = 10) and this was not affected when extracellular sodium was replaced by choline (6.3 +/- 1.2 mV; n = 10). The depolarizations induced by L-phenylalanine and L-arginine were significantly additive (p less than 0.001). The intracellular pH of OK cells was 7.09 +/- 0.03 (n = 11) and did not change during L-arginine application. We conclude that (1) carrier-mediated uptake of neutral and dibasic amino acids into OK cells is at least partially electrogenic. (2) L-Phenylalanine is transported by a Na+-symport. (3) In contrast, L-arginine depolarizes PDm independently of extracellular sodium. (4) Electrogenic uptake of acidic amino acids is not detectable in OK cells.

An inwardly-directed sodium-amino acid cotransporter influences steady-state cell volume in slices of rat renal papilla incubated in hyperosmotic media

The effect of a neutral amino acid, 2-aminoisobutyric acid (AIB) on steady state cell volume has been examined in rat renal papillary slices incubated in hyperosmotic media (2,000 mosmol/kg H2O) containing high concentrations of NaCl and urea (thus imitating papillary interstitial fluid in the intact kidney during antidiuresis). Volumes were significantly increased (P less than 0.001) when external AIB was raised from 0.1 to 10 mmol/l. Na+-dependent AIB uptake occurred, and there were net increases in cell contents of Na+ and Cl-. Replacement of Na+ by Li+, but not by other cations, did not influence the effect of AIB concentration on cell volume, but this was abolished when Cl- was replaced by other anions. The effect of AIB was abolished by diphenylamine-2-carboxylate (10(-3) mmol/l), bumetanide (at 1 mmol/l but not 10(-2) mmol/l) and by N,N'-dicyclohexylcarbodiimide (0.5 mmol/l), but not by amiloride (1 mmol/l) or 4-acetamido-4'-iso-thiocyanato-stilbene-2,2'-disulphonic acid (1 mmol/l), and was enhanced by the presence of Ba2+ or quinine (1 mmol/l). The findings are interpreted in terms of an inwardly-directed Na+-amino acid cotransporter, which determines steady-state volume, requires simultaneous entry of Cl- through conductive pathways, and whose effects on cell volume are moderated by K+ efflux through volume-sensitive K+ channels.

On the nature of delayed repolarization during sustained sodium coupled transport in frog proximal tubules

In proximal tubules of the frog kidney, stimulation of coupled transport of sodium with phenylalanine leads to depolarization of the cell membrane, followed by repolarization within a few minutes. The repolarization is due to a delayed increase of potassium conductance at the peritubular cell membrane. The present study was designed to test for the role of depolarization, of calmodulin and of arachidonic acid metabolites for the delayed increase of potassium conductance. To this end, the potential difference across the peritubular cell membrane of proximal convoluted tubules (PDpt) has been recorded continuously during exposure of the lumen to phenylalanine or during galvanic current injection into a neighbouring cell. During control conditions, PDpt averages -68.6 +/- 1.0 mV (n = 45). Phenylalanine leads to a depolarization of the peritubular cell membrane by +31.5 +/- 1.3 mV (n = 20), followed by a repolarization by -12.9 +/- 1.1 mV (n = 20) within 3 min. Injection of currents from 10 to 80 nAmps leads to a depolarization by +0.83 +/- 0.01 mV/nAmps which is again followed by repolarization. A linear correlation is observed between the magnitude of depolarization (dep) and repolarization (rep) within 3 min: rep (mV) = -(0.24 +/- 0.01) dep (mV) +(2.45 +/- 0.12) mV (r = 0.90). Thus, depolarization is capable to trigger delayed repolarization. The extent of repolarization is a function of the magnitude of depolarization. The possible involvement of calmodulin or arachidonic acid metabolites has been tested for by inducing sodium coupled transport in the presence of 100 mumol/l mepacrine, 10 mumol/l indomethacin or 10 mumol/l trifluoperazine.

Chloride dependence of the sodium-dependent glycine transport in pig kidney cortex brush-border membrane vesicles

The Na+-dependent glycine uptake in pig kidney cortex brush-border membrane vesicles is specifically enhanced by the presence of Cl-. The Na+-independent glycine uptake is not affected by Cl-. Various anions tested could not substitute Cl- in the activation of the Na+-dependent glycine transport. Cl- is specifically required on the outer membrane side. The Na+-dependent glycine uptake is higher in the presence of an inwardly directed Cl- gradient than the one measured in the presence of equilibrated Cl-. The Na+-dependent glycine uptake depends on, and is saturable at increasing Cl- concentrations. By studying the activation of glycine uptake by Na+ in the presence and in the absence of Cl-, evidence was found that two different Na+-dependent glycine transport pathways are present in pig kidney cortex brush-border membrane vesicles. The kinetics of the glycine uptake measured in the presence of an inwardly directed NaCl gradient show the presence of two glycine transport systems, a low-affinity, high-capacity one and a high-affinity, low capacity one. In the absence of Cl- the high-affinity, low-capacity transport is almost suppressed, thus indicating the presence of a high-affinity glycine transport system simultaneously dependent on both Na+ and Cl- ions.

Influence of glucose absorption on ion activities in cells and submucosal space in goldfish intestine

Mucosal glucose addition evokes in goldfish intestinal epithelium a fast depolarization of the mucosal membrane potential (delta psi mc = 12 mV) followed by a slower repolarization (delta psi mc = -7 mV). The intracellular sodium activity, aiNa+, rises from 13.2 +/- 2.4 meq/l by 6.7 +/- 0.5 meq/l within 5 min, aiCl- rises about 3 meq/l above the control value of 37.7 +/- 2.2 meq/l, while aiK is constant (97.7 +/- 7.4 meq/l). The potassium activity measured in the submucosal interstitium near the basal side of the cells (asK+) is 5.2 +/- 0.2 meq/l in non-absorbing tissue compared to 4.2 meq/l in the bathing solution and shows a transient increase due to glucose absorption (1.1 +/- 0.1 meq/l). In chloride-free media asK+ = 4.2 +/- 0.1 meq/l and psi mc hyperpolarizes by -13 mV. The depolarization due to glucose absorption increases (delta psi mc = 14.1 +/- 1.4) and the repolarization (delta psi repolmc) disappears. In addition, aiNa+ rises from 16.3 +/- 2.4 meq/l by 9.9 +/- 1.5 meq/l within 5 min, aiK+ remains constant and equal to the value in chloride containing solutions (88.5 +/- 2.8 meq/l); asK+ increases transiently (1.1 +/- 0.1 meq/l). Serosal Ba2+ (5 mM) depolarizes psi mc (+14.2 +/- 1.0 mV) and abolishes the repolarization. Increased serosal or mucosal potassium activity depolarizes psi mc and abolishes the repolarization. These effects are discussed in terms of changes of ion activities, the basolateral potassium conductance, the influence of intracellular Ca2+, the functional state of the Na/K-pump, and modulation of membrane permeabilities by extracellular potassium.

Glutamine transport in the rabbit proximal straight tubule: effect of acute acid pH

Proximal straight tubules (PST) has been shown to be an important nephron segment of renal ammonia production. To clarify the nature of glutamine (substrate of ammonia production) transport in PST, both luminal resorption and peritubular uptake of glutamine were measured in isolated rabbit PST. Luminal glutamine resorption (Jgln) was measured at various perfusate glutamine concentration (0.05 to 20 mM) at 38 degrees C and 12 degrees C. Jgln measured at 12 degrees C were proportional to mean luminal glutamine concentrations. This flux was thought to be a passive glutamine flux. The flux, which was obtained by subtracting passive glutamine flux from Jgln obtained at 38 degrees C, was thought to be active luminal resorption. This flux exhibited saturation kinetics (Vmax 20.9 pmol min-1 X mm-1, km 5.2 mM). When bath pH (HCO3) was lowered from 7.4 to 6.8, Jgln showed no change or a small decrease (12%) at perfusate glutamine concentrations of 0.05 or 5 mM, respectively. When perfusate pH (HCO3) was lowered from 7.4 to 6.8 Jgln showed a small decrease (10%) at 5 mM perfusate glutamine concentration. Peritubular glutamine uptake was determined in isolated nonperfused PST incubated for 5 to 50 min in [14C]-glutamine containing solution. When incubated in pH 7.4 HCO3 buffer solution, cell to medium 14C concentration ratio was higher than unity (3.83 +/- 0.34, P less than 0.001) at 5 min, and reached a maximum (11.37 +/- 1.13) at 30 min.(ABSTRACT TRUNCATED AT 250 WORDS)

Influence of barium on the effects of phenylalanine in proximal tubules

The present study was designed to further test for the role of peritubular potassium conductance in the repolarization of peritubular cell membrane during sustained stimulation of sodium coupled transport by phenylalanine. To this end the potential difference across the peritubular cell membrane (PDpt) has been recorded continuously, while 10 mmol/l phenylalanine (Phe) were added to the luminal perfusate, both in the presence or absence of peritubular or luminal barium (1 mmol/l). In the absence of phenylalanine and barium, PDpt amounts to -65.5 +/- 2.2 mV. Phe leads to a rapid depolarization of the peritubular cell membrane by +36.2 +/- 2.2 mV within 30 s, followed by an almost complete repolarization by -28.9 +/- 2.6 mV within 7 min. In the presence of barium in peritubular perfusate, the depolarization following Phe is +24.3 +/- 2.6 mV and the repolarization almost abolished (-4.3 +/- 0.9 mV). In the presence of barium in luminal perfusate, Phe leads to a depolarization by +35.7 +/- 2.4 mV followed by a repolarization of -17.0 +/- 3.2 mV within 7 min. It is concluded that the repolarization during sustained stimulation of sodium coupled transport is in large part due to alterations of peritubular potassium conductance.

Excitatory transmitter release induced by high concentrations of gamma-aminobutyric acid (GABA) in crayfish neuromuscular junctions

At the neuromuscular junction of very small crayfish (0.4-2 g) addition of gamma-aminobutyric acid (GABA) to the superfusing solution at concentrations exceeding 100 mmol/l elicited high frequency release of excitatory transmitter quanta. In seven experiments single application of 500 mmol/l GABA gave rise to instantaneous release of 70,000 to 130,000 quanta. These stores of transmitter were released by GABA in a first order process with time constants, tau q, of between 9 s and 20 s, the maximum rate of release, ñ0, reaching 10,000 quanta/s in some cases. After release had ceased in the presence of GABA, the preparation was allowed to recover for five minutes in normal solution. Subsequently, a second trial evoked about 50% of the release induced during the first application of GABA. Pretreatment of the preparation with 2 mumol/l serotonin (5-HT) facilitated GABA-induced transmitter release resulting in larger rates of release and consequently in a larger output of transmitter by a factor of about 3. The largest amount of transmitter released on a single application of GABA in the presence of serotonin comprised about 220,000 quanta with a maximum rate of release ñ0 approximately equal to 25,000 quanta/s. The release evoked by high GABA-concentrations did not depend markedly on extracellular Ca2+ or Mg2+, but required extracellular Na+. The effects induced by high concentrations of GABA on release of excitatory transmitter quanta were quantitatively similar to the effects of high glycine-concentrations on release of quanta from the inhibitory terminals (Finger 1983a, b).

Metabolic control of renal vascular resistance and glomerulotubular balance

Renal vascular resistance (RVR) and glomerulotubular balance were examined in isolated rat kidneys perfused at 100 mm Hg with 10 mM lactate (L) or 10 mM pyruvate (P) or 5 mM glucose (G) either alone or with a mixture of 20 amino acids (13.5 mM, AA); albumin oncotic pressure 24 +/- 1 mm Hg. RVR was L greater than P greater than G = AA. Vasodilation by G and AA was additive. Proximal tubular sodium-cotransport was evaluated from fractional reabsorption (FR) of phosphate (Pi), G, and L. FR Pi was 91% in AA, 86% in P, 72% in L, and 67% in G. Combining AA or P with L or G increased FR Pi to 89 to 90%. FRs of G and L by G and L perfused kidneys were 83 and 78%, respectively, and were increased to 97 to 99% by combining G or L with AA or P. P and AA also increased FR sodium and FR water when combined with L or G or when combined with each other. GFR correlated positively with FR sodium and FR water. AA combined synergistically with L to increase gluconeogenesis. These results indicate that, compared with pyruvate or AA, neither glucose nor lactate alone is a good energy source for proximal tubular reabsorption, that synergistic interactions between AA or pyruvate and lactate or glucose augment GFR by increasing proximal tubular reabsorption, and that the vasodilating effects of glucose and AA are not related directly to their effects on GFR.

Localisation of alanine uptake by cultured renal epithelial cells (LLC-PK1) to the basolateral membrane

Alanine uptake by LLC-PK1 cells has previously been demonstrated to be almost exclusively sodium dependent. We here confirm that when the cells are grown on an impermeable substratum there is a marked fall in uptake as confluence is reached. By applying an autoradiographic technique to visualize transported alanine, it is clear, however, that even in subconfluent cultures there is marked cellular inhomogeneity with regard to uptake, which takes place predominantly in those cells at the periphery of growing islands and not those at the interior. In contrast, when cells are grown on permeable substrata, a uniform distribution of silver grains is found. In two other types of experiment, we found that when confluent cell monolayers on an impermeable support were treated briefly with a chelating agent or suspended by mechanical treatment, there was a marked increase per cell in sodium-dependent alanine uptake and in ouabain-sensitive potassium uptake. We conclude that the apparent fall in alanine uptake as cells reach confluence on an impermeable support is due to masking of transport sites, which are predominantly, if not exclusively, located at the basolateral membrane.

Sodium-dependent sugar and amino acid transport in isolated goldfish intestinal epithelium: electrophysiological evidence against direct interactions at the carrier level

The effects of mucosal application of monosaccharides and amino acids on transepithelial and membrane potentials in isolated goldfish intestinal epithelium were investigated. Isosmotic replacement of mucosal mannitol by sugars or L-amino acids resulted in a rapid depolarization of the mucosal membrane potential psi mc followed by a slow repolarization. Phlorizin inhibited the responses to sugar but not those to amino acids. D-Amino acids did not induce any electrical response in the epithelium. Dose-response curves for L-amino acids showed simple saturation. Simultaneous application of L-amino acid and glucose induced transepithelial responses of about 80% of the sum of the separate responses to the application of amino acid or glucose alone. Simultaneous application of different amino acids in saturating concentrations did not increase the magnitude of the electrical responses. From the measured changes in potentials we calculated the change in electromotive force across the mucosal (delta Em) and serosal (delta Es) membrane. The change in Em induced by combined application of alanine and glucose was 90% of the sum of the calculated values induced by glucose and alanine alone. The response of Es to both substrates was accelerated with respect to that of separate substrates alone. We conclude that by application of glucose in addition to alanine the influx of sodium is increased, thereby stimulating the basolaterally located electrogenic Na+/K+-pump. There are no indications for direct interaction of sugars and amino acids at the mucosal membrane of the intestinal epithelial cell.

Transport of L-cystine by rat renal brush border membrane vesicles

Brush border membranes were isolated from rat renal cortex by a divalent cation precipitation method. L-35S-cystine uptake into the vesicles was measured by a rapid filtration method. Covalent incorporation of tracer into membrane proteins was observed after prolonged incubations. At short incubation periods (1 min) binding was small and allowed an analysis of transmembrane transport. To guarantee transport of L-cystine, the experiments were performed in the presence of the oxidant diamide. Sodium stimulated L-cystine uptake specifically. A potassium/valinomycin induced inside negative diffusion potential stimulated sodium dependent L-cystine transport. Thus, transport is potential sensitive in the presence of sodium. At low substrate and inhibitor concentrations, L-cystine transport was inhibited by L-lysine, L-ornithine and L-arginine but not by D-lysine in the presence and absence of sodium. At higher inhibitor concentration, the neutral amino acids L-phenylalanine and L-leucine also inhibited L-cystine uptake, but only the sodium dependent uptake. These inhibition experiments suggest that L-cystine is transported by the brush border membrane by a transport system for basic amino acids not necessarily requiring sodium. In addition, transport of L-cystine can also proceed via sodium dependent transport pathways for neutral amino acids. In the concentration range tested (up to 0.225 mmoles/l), no saturation of L-cystine transport was observed in the presence and absence of sodium.

Transport of L-cysteine by rat renal brush border membrane vesicles

Brush border membranes were isolated from rat renal cortex by a divalent cation precipitation method. L-35S-cysteine uptake into the vesicles was measured by a rapid filtration method. Only minimal binding of the amino acid to the vesicles was observed. Sodium stimulates L-cysteine uptake specifically. Anion replacement experiments, experiments in the presence of potassium/valinomycin-induced diffusion potential as well as experiments with a potential-sensitive fluorescent dye document an electrogenic sodium-dependent uptake mechanism for L-cysteine. Tracer replacement experiments as well as the fluorescence experiments indicate a preferential transport of L-cysteine. Transport of L-cysteine is inhibited by L-alanine and L-phenylalanine but not by L-glutamic acid and the L-basic amino acids. Initial, linear influx kinetics provide evidence for the existence of two transport sites. The results suggest (a) sodium-dependent mechanism(s) for L-cysteine shared by other neutral amino acids.

Transport of inorganic and organic substances in the renal proximal tubule

The transport through the epithelial cell layer of the renal proximal tubule proceeds in principle by passive paracellular and active transcellular transport. The active transcellular transport is mostly secondary active. This means it proceeds coupled with the flux of Na+ ions, whereby the transcellular gradient of sodium, created by the (Na+ + K+)-ATPase, located at the contraluminal cell side, provides the main driving force. Once in the cell the substances leave the other cell side by a Na+ -independent, but carrier-mediated transport system. Using microperfusion and electrophysiological techniques as well as brush border membrane vesicle preparation the Na+ -H+ countertransport and the Na+-cotransport of amino acids, phosphate, sulfate, thiosulfate, bile acids, aliphatic-aromatic monocarboxylic acids (lactate) and dicarboxylic acids was studied. Special emphasis will be given to the bidirectional transport of thiosulfate as well as to the specificity of the monocarboxylic acid and dicarboxylic acid transport system.

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.

Electrophysiological analysis of rat renal sugar and amino acid transport. II. Dependence on various transport parameters and inhibitors

Transepithelial and cellular electrical potential changes were measured in response to luminal perfusion of D-glucose and related substrates in micropuncture experiments on rat kidney in vivo. By studying the dependence of the potential response on various experimental parameters, some insight was obtained into the mechanism of Na+ coupled glucose absorption. The experiments confirm the driving forces for glucose absorption in the living cell to be: a) the Na concentration gradient, b) the electrical potential gradient and c) the glucose concentration gradient across the brush-border membrane. Furthermore they describe the substrate specificity of the cotransport mechanism and the mechanism of inhibition of D-glucose transport by various inhibitors, such as phlorizin, harmaline and ouabain. The latter experiments suggest that the active Na+ pump in the peritubular cell membrane, which establishes the Na+ ion gradient and the electrical potential gradient across the brushborder, contributes a measurable partial conductance to the overall electrical conductance of the peritubular cell membrane.

Electrophysiological analysis of rat renal sugar and amino acid transport. I. Basic phenomena

The electrical events associated with the absorption of D-glucose or L-amino acids in renal proximal tubules were studied in microperfusion experiments on rat kidneys in vivo. Intratubular application of these substrates led concomitantly to: 1) a shift of the transepithelial potential into lumen negative direction, 2) a partial depolarization of the tubular cell membranes and 3) a reduction of the electrical resistance of the brushborder membrane. By means of rapid perfusion experiments it was possible to discern two phases in the potential response to substrate perfusion, a fast initial response which reflects a substrate-induced Na+ ion current from lumen to cell, and a slower secondary response which reflects the relaxation of the intracellular ion and substrate concentrations towards new steady states. A quantitative analysis of the data yielded estimates of 1) the apical (Ra) and basal (Rb) cell membrane resistances and of the shunt resistance, Rs, of rat proximal tubule of approximately Ra = 255 omega cm2, Rb = 92 omega cm2 and Rs = 5 omega cm2 (all referred to the quasi macroscopic surface area of the tubular lumen), 2) the conductance of the Na+ and glucose cotransport pathway and 3) the driving forces acting on the cotransport mechanism in the brushborder membrane. The latter were found to be a) the electrical cell membrane potential of -74 mV, b) the Na+ ion concentration gradient between the tubular lumen (clumNa = 145 mmol/l) and the cytoplasm (ccellNa approximately 33 mmol/l) which corresponds to an additional equivalent potential of 51 mV and c) the substrate concentration gradient, which varies according to the experimental conditions. Moreover the analysis provided a quantitative estimate of the relationship between the substrate-induced changes in transepithelial potential or short circuit current and the actual cotransport current in the brushborder membrane. Based on this analysis it is concluded that the stoichiometry of Na+ and glucose flux coupling in the brushborder membrane of rat proximal tubule is close to 1.0.