Revealing key interactions in the metabolic network: a model of primary phosphate transport in bacteria]

One of the main problems of metabolic engineering is to determine the genetically controlled limiting links of a metabolic network. We have built a model of the primary transport of inorganic phosphates (Pi), analyzed the Pi metabolic network in Gram-negative bacteria, and determined the factors controlling the phosphate exchange. The model explains why the Pi primary transport is not observed at the release stage. The nonlinearity of primary transport and the differences in its parameters in the membrane and within the cell give rise to transport asymmetry, i.e., the Pi release rate is low as compared with the uptake rate, and is small at the background of secondary transport. Discussed is a general scheme of coordination between primary and secondary transport, which are interconnected through the substrate-product reration.     

The renal type IIa Na/Pi cotransporter: structure-function relationships

The type IIa Na/P_i cotransporter mediates proximal tubular brush-border membrane secondary active phosphate (P_i) flux. It is rate limiting in tubular P_i reabsorption and, thus, a final target in many physiological and pathophysiological situations of altered renal P_i handling (1–4). In the present short review, we will briefly summarize our current knowledge about the transport mechanism (cycle) as well as particular regions of the transporter protein (“molecular domains”) that potentially determine transport characteristics.     

COMPETITION BETWEEN STAURASTRUM LUETKEMUELLERII (CHLOROPHYCEAE) AND MICROCYSTIS AERUGINOSA(CYANOPHYCEAE) UNDER VARYING MODES OF PHOSPHATE SUPPLY1

The desmid Staurastrum luetkemuellerii Donat et Ruttner and the cyanobacterium Microcystis aeruginosa Kütz. were grown in mixed cultures with various phosphate (P_i) additions. One pulse of P_i each day (semi-continuous cultures) favored M. aeruginosa whereas S. luetkemuellerii was favored when the same quantity of P_i was supplied continuously (chemostats). Both species coexisted under P limitation provided that the nutrient was supplied in an appropriate mode. The ability of each species to compete for P depended on their P_i uptake characteristics and their capability to retain the accumulated P_i. High affinity in uptake at low P_i concentrations contributed considerably to the growth eficiency of S. luetkemuellerii under continuous supply of P_iM. aeruginosa was, however, consistently superior to S. luetkemuellerii in accuniulatiug the newly added P, but had a high rate of P_i release. In both -types of cultures, a net high of P went from M. aeruginosa to S. luetkemuellerii. The kinetic characteristics of the two species were used to simulate the outcome of competition experiments. Simulations agreed with the experimental data f both uptake and P_i release were considered in the model. The zlariable P*(the concentration of P_i at which the net uptake is equal to μ·Q_P is a function of uptake and release of P_i but could not explain the chemostat results. S. luetkemuellerii was the winner in many experiments even if its P*was higher thou that of M. aeruginosa. Thus, in the present case P_c (the concentration at which the net uptake is zero) was a better predictor of the ability to compete for P_i under steady state as well as transient conditions in the P_i supply.     

Proton- and sodium-coupled phosphate transport systems and energy status of Yarrowia lipolytica cells grown in acidic and alkaline conditions

In this study we have used a newly isolated Yarrowia lipolytica yeast strain with a unique capacity to grow over a wide pH range (3.5–10.5), which makes it an excellent model system for studying H⁺- and Na⁺-coupled phosphate transport systems. Even at extreme growth conditions (low concentrations of extracellular phosphate, alkaline pH values) Y. lipolytica preserved tightly-coupled mitochondria with the fully competent respiratory chain containing three points of energy conservation. This was demonstrated for the first time for cells grown at pH 9.5–10.0. In cells grown at pH 4.5, inorganic phosphate (P_i) was accumulated by two kinetically discrete H⁺/P_i-cotransport systems. The low-affinity system is most likely constitutively expressed and operates at high P_i concentrations. The high-affinity system, subjected to regulation by both extracellular P_i availability and intracellular polyphosphate stores, is mobilized during P_i-starvation. In cells grown at pH 9.5–10, P_i uptake is mediated by several kinetically discrete Na⁺-dependent systems that are specifically activated by Na⁺ ions and insensitive to the protonophore CCCP. One of these, a low-affinity transporter operative at high P_i concentrations is kinetically characterized here for the first time. The other two, high-affinity, high-capacity systems, are derepressible and functional during P_i-starvation and appear to be controlled by extracellular P_i. They represent the first examples of high-capacity, Na⁺-driven P_i transport systems in an organism belonging to neither the animal nor bacterial kingdoms. The contribution of the H⁺- and Na⁺-coupled P_i transport systems in Y. lipolytica cells grown at different pH values was quantified. In cells grown at pH values of 4.5 and 6.0, the H⁺-coupled P_i transport systems are predominant. The contribution of the Na⁺/P_i cotransport systems to the total cellular P_i uptake activity is progressively increased with increasing pH, reaching its maximum at pH 9 and higher. Received: 15 December 2000/Revised: 14 May 2001     

Phosphate concentration and transport in Ehrlich ascites tumor cells: Effect of sodium

The effects of extracellular P_i and Na⁺ on cellular P_i concentration and transport were studied. Steady-state P_i exchange flux was measured by ³²P uptake in the presence and absence of Na⁺. Model experiments were also conducted to assess the possibility that hydrolysis of organic phosphate esters contributes to the chemically measured intracellular P_i concentration of Ehrlich ascites tumor cells. The results of these experiments indicate that hydroloysis of labile organic phosphate esters does not contribute to the measured intracellular pool of P_i. The P_i transport system exhibits an apparent K_s of 0.115 mM P_i and a maximal flux of 1.73 mmole min^?1 (kg dry wt)^?1. When incubated in a phosphate-buffered choline chloride medium (5 mM P_i) the intracellular P_i and the P_i influx fall by 65 and 88%, respectively. At 5 mM extracellular P_i, the Na⁺-dependent component of P_i transport fits Michaelis-Menten kinetics with the maximal flux equal to 2.46 mmole min^?1 (kg dry wt)^?1 and an apparent K_s of 35.4 mM Na⁺. In addition, a Na⁺-independent component of P_i transport, comprising about 12% of the total P_i flux, was identified. The data support the hypothesis that a P_i transport system, dependent on Na⁺, plays a principal role in the maintenance of intracellular P_i concentration.     

Phosphate carrier of liver mitochondria: The reaction of its SH groups with mersalyl, 5,5′-dithio-bis-nitrobenzoate,andN-ethylmaleimide and the modulation of reactivity by the energy state of the mitochondria

The inhibitory effect of three SH reagents, mersalyl, 5,5-dithio-bis-nitrobenzoate, andN-ethylmaleimide, on P_i transport in rat liver mitochondria was investigated under a variety of conditions. Mersalyl binds at room temperature with both high (K _d<10 µM) and low affinity to mitochondria. Inhibition of P_i transport by mersalyl goes in parallel with titration of the high-affinity sites, inhibition being complete when 3.5–4.5 nmol/mg protein is bound to the mitochondria. At concentrations of mersalyl equal to or higher than 10 µM, inhibition of P_i transport occurs in less than 10 sec. At concentrations of mersalyl lower than 10 µM, the rate of reaction with the P_i carrier is considerably decreased. At a concentration of 100 µM, 5,5-dithio-bisnitrobenzoate fully inhibits P_i transport in about 1 min at room temperature. Nearly total inhibition is attained when as little as 40–50 pmol/mg is bound to mitochondria. Upon incubation longer than 1 min, additional SH groups, not belonging to the P_i carrier, begin to react. The uncoupler carbonyl cyanidep-trifluoromethoxyphenylhydrazone decreases the rate of reaction of mersalyl, 5,5-dithio-bis-nitrobenzoate, andN-ethylmaleimide with the P_i carrier. Preincubation with P_i has a similar effect. We propose that both carbonyl cyanidep-trifluoromethoxyphenylhydrazone and P_i act by increasing the acidity of the mitochondrial matrix. Protonation of the P_i carrier at the matrix side would change the accessibility of its SH groups at the outer surface of the inner membrane. This might correspond to a membrane-Bohr effect, possibly related to the opening of a gating pore in the P_i carrier.     

Phosphate transport in mitochondria and submitochondrial particles: The influence of thiol oxidation

Diamide, a thiol oxidizing agent, partially inhibited P _i uptake by rat liver mitochondria. The inhibition was temperature dependent; at 20°C, the optimal temperature for maximum inhibitory effect, diamide also reduced the minimal amount of mersalyl required for the inhibition of P _i transport. Under the same conditions no inhibitory effect on P _i efflux was observed. The amount of mitochondrial thiol groups titrated by the amounts of diamide needed for the inhibition of P _i uptake was on the order of 5 nmole/mg protein. Unlike liver mitochondria, the P _i transport system of heart mitochondria was insensitive to diamide. On the contrary, accumulation of P _i into submitochondrial heart vesicles, previously loaded with MnCl₂, was inhibited by diamide. These results outline the different positional character of membrane thiol groups of mitochondria from various sources, and provide further evidence of an asymmetric orientation of the P _i transport system in mitochondrial membranes.     

Intracellular phosphate and its possible role as an exchange anion for active transport of methotrexate in L1210 cells

L1210 cells transport P_i in the absence of added Na⁺. Uptake shows saturation kinetics (K_t = 1.7 mM), is temperature-dependent, and can be reduced 80% by high levels of unlabeled P_i, and thus has the characteristics of a carrier-mediated process. This transport process is also inhibited by methotrexate. The methotrexate-sensitive component constitutes half of total P_i uptake, and is reduced by 50% at a concentration of methotrexate (2 μM) that is comparable to its K_t (1.5 μM) for transport into the cells. An impermeable fluorescent analog of methotrexate and an irreversible inhibitor of the methotrexate transport system (carbodiimide-activated methotrexate) also inhibit this same P_i uptake component. It is concluded that methotrexate and P_i can be transported by the same carrier system. The basis for this shared uptake is suggested to be that the methotrexate carrier protein facilitates the obligatory exchange of extracellular folate compounds for intracellular divalent anions, and that a primary exchange anion is P_i. A principal energy source for active transport of methotrexate might then be the concentration gradient for P_i that is maintained by the Na⁺-dependent, P_i transport system of these cells.     

Proton-coupled high-affinity phosphate transport revealed from heterologous characterization in Xenopus of barley-root plasma membrane transporter, HvPHT1;1

High‐affinity phosphate transporters mediate uptake of inorganic phosphate (P_i) from soil solution under low P_i conditions. The electrophysiological properties of any plant high‐affinity P_i transporter have not been described yet. Here, we report the detailed characterization of electrophysiological properties of the barley P_i transporter, HvPHT1;1 in Xenopus laevis oocytes. A very low K_m value (1.9 µm ) for phosphate transport was observed in HvPHT1;1, which falls within the concentration range observed for barley roots. Inward currents at negative membrane potentials were identified as nH⁺:P_i^‐ (n > 1) co‐transport based on simultaneous P_i radiotracer uptake, oocyte voltage clamping and pH dependence. HvPHT1;1 showed preferential selectivity for P_i and arsenate, but no transport of the other oxyanions SO₄^2? and NO₃^‐. In addition, HvPHT1;1 locates to the plasma membrane when expressed in onion (Allium cepa L.) epidermal cells, and is highly expressed in root segments with dense hairs. The electrophysiological properties, plasma membrane localization and cell‐specific expression pattern of HvPHT1;1 support its role in the uptake of P_i under low P_i conditions.     

Properties of the phosphate and phosphite transport systems of Phytophthora palmivora

Germlings of Phytophthora palmivora possess at least two systems for the uptake of inorganic phosphate (P_i). The first is synthesized on germination in medium containing 50 M P_i and has a K_m of approx. 30 M (V_max=7–9 nmol P_i/h·10⁶ cells). The second is synthesized under conditions of P_i-deprivation and has a higher affinity for P_i (K_m=1–2 M), but a lower V_max (0.5–2 nmol P_i/h·10⁶ cells). The fungicide phosphite likewise enters the germlings via two different transport systems, the synthesis of which also depends on the concentration of P_i in the medium. The K_m of the lower affinity system is 3 mM (V_max=20 nmol phosphite/h·10⁶ cells) and that of the higher affinity system is 0.6 mM (V_max=12 nmol/h·10⁶ cells). P_i and phosphite are competitive inhibitors for each other's transport in both systems. However, whereas mM concentrations of phosphite are necessary to inhibit P_i transport, only M concentrations of P_i are required to inhibit phosphite transport. A third system of uptake for P_i also exists, since when phosphate-deprived cells are presented with mM concentrations of P_i, they transport the anion at a very high rate (around 100 nmol/h·10⁶ cells). High rates of transport of phosphite are also observed when these cells are presented with mM concentrations of this anion.     

A Biophysical Model of the Mitochondrial ATP-Mg/Pi Carrier

Mitochondrial adenine nucleotide (AdN) content is regulated through the Ca²⁺-activated, electroneutral ATP-Mg/P_i carrier (APC). The APC is a protein in the mitochondrial carrier super family that localizes to the inner mitochondrial membrane (IMM). It is known to modulate a number of processes that depend on mitochondrial AdN content, such as gluconeogenesis, protein synthesis, and citrulline synthesis. Despite this critical role, a kinetic model of the underlying mechanism has not been developed and validated. Here, a biophysical model of the APC is developed that is thermodynamically balanced and accurately reproduces a number of reported data sets from isolated rat liver and rat kidney mitochondria. The model is based on an ordered bi-bi mechanism for heteroexchange of ATP and P_i and includes homoexchanges of ATP and P_i to explain both the initial rate and time course data on ATP and P_i transport via the APC. The model invokes seven kinetic parameters regarding the APC mechanism and three parameters related to matrix pH regulation by external P_i. These parameters are estimated based on 19 independent data curves; the estimated parameters are validated using six additional data curves. The model takes into account the effects of pH, Mg²⁺, and Ca²⁺ on ATP and P_i transport via the APC, and supports the conclusion that the pH gradient across the IMM serves as the primary driving force for AdN uptake or efflux. Moreover, computer simulations demonstrate that extramatrix Ca²⁺ modulates the turnover rate of the APC and not the binding affinity of ATP, as previously suggested.     

Characterization of Na+-Dependent Phosphate Uptake in Cultured Fetal Rat Cortical Neurons

Abstract: Our laboratory has recently cloned and expressed a brain- and neuron-specific Na⁺-dependent inorganic phosphate (P_i) cotransporter that is constitutively expressed in neurons of the rat cerebral cortex, hippocampus, and cerebellum. We have now characterized Na⁺-dependent ³²P_i cotransport in cultured fetal rat cortical neurons, where >90% of saturable P_i uptake is Na⁺-dependent. Saturable, Na⁺-dependent ³²P_i uptake was first observed in primary cultures of cortical neurons at 7 days in vitro (DIV) and was maximal at 12 DIV. Na⁺-dependent P_i transport was optimal at physiological temperature (37°C) and pH (7.0–7.5), with apparent K_m values for P_i and Na⁺ of 54 ± 12.7 µM and 35 ± 4.2 mM, respectively. A reduction in extracellular Ca²⁺ markedly reduced (>60%) Na⁺-dependent P_i uptake, with a threshold for maximal P_i import of 1–2.5 mM CaCl₂. Primary cultures of fetal cortical neurons incubated in medium where equimolar concentrations of choline were substituted for Na⁺ had lower levels of ATP and ADP and higher levels of AMP than did those incubated in the presence of Na⁺. Furthermore, a substantial fraction of the ³²P_i cotransported with Na⁺ was concentrated in the adenine nucleotides. Inhibitors of oxidative metabolism, such as rotenone, oligomycin, or dinitrophenol, dramatically decreased Na⁺-dependent P_i import rates. These data establish the presence of a Na⁺-dependent P_i cotransport system in neurons of the CNS, demonstrate the Ca²⁺-dependent nature of ³²P_i uptake, and suggest that the neuronal Na⁺-dependent P_i cotransporter may import P_i required for the production of high-energy compounds vital to neuronal metabolism.     

NAD+-induced inhibition of phosphate transport in canine renal brush-border membranes Mediation through a process other than or in addition to NAD+ hydrolysis

We previously demonstrated inhibition of Na⁺-dependent ³²P_i transport in canine renal brush-border membranes in association with NAD⁺-induced ADP ribosylation of membrane protein(s) and postulated that NAD⁺ inhibits P_i transport across the brush-border membrane via ADP ribosylation. Recently it was shown that incubation of rat brush-border membrane with NAD⁺ resulted in release of P_i which was prevented by EDTA. It was proposed that NAD⁺-mediated inhibition of ³²P_i transport might occur through this mechanism. To determine whether NAD⁺ inhibited ³²P_i transport by a mechanism other than or in addition to release of P_i, we compared Na⁺-dependent ³²P_i counterflow in brush-border membrane equilibrated with P_i or with P_i generated from NAD⁺. Release of P_i from NAD⁺ incubated with brush-border membrane was confirmed. The increased uptake of ³²P_i which was demonstrated in brush-border membrane equilibrated with P_i was not measured when intravesicular P_i was generated from a concentration of NAD⁺ which effected ADP-ribosylation of brush border membranes (100 μM NAD⁺). In contrast, increased uptake of ³²P_i was demonstrated when intravesicular P_i was generated from 1 μM NAD⁺ which did not effect ADP ribosylation. Mg²⁺-dependent ADP ribosylation of brush-border membrane incubated with NAD⁺ was demonstrated which persisted during the time interval of ³²P_i uptake measurements. Our findings are compatible with the hypothesis that NAD⁺-induced ADP ribosylation of brush-border membrane protein(s) results in inhibition of P_i transport across the membrane in vivo. EDTA may act to prevent this inhibition in brush-border membrane by chelation of Mg²⁺ and decreased ADP ribosylation.     

Phosphate transport system inParacoccus denitrificans

P_i uptake in cells or spheroplasts ofParacoccus denitrificans is biphasic; only the first rapid phase represents net P_i transport. The second phase is limited by the rate of P_i utilization inside the cell, i.e., mainly by its esterification, and as such it was inhibited by DCCD. The P_i/dicarboxylate antiporter does not seem to be operative, and its inhibitorn-butylmalonate did not exert specific inhibition. P_i transport is inhibited by SH reagents; the most potent inhibitor is PCMB, and mersalyl is much less effective. However, neither inhibitor affects efflux of accumulated P_i. The gradient of potassium ions may be involved in the P_i uptake, which is lowered in the presence of valinomycin. FCCP alone does not release accumulated P_i from spheroplasts unless they are preincubated with SCN^?. The results indicate that P_i enters the cell by symport with protons.     

Temporal development of the barley leaf metabolic response to Pi limitation

The response of plants to P_i limitation involves interplay between root uptake of P_i, adjustment of resource allocation to different plant organs and increased metabolic P_i use efficiency. To identify potentially novel, early‐responding, metabolic hallmarks of P_i limitation in crop plants, we studied the metabolic response of barley leaves over the first 7 d of P_i stress, and the relationship of primary metabolites with leaf P_i levels and leaf biomass. The abundance of leaf P_i, Tyr and shikimate were significantly different between low Pi and control plants 1 h after transfer of the plants to low P_i. Combining these data with ¹⁵N metabolic labelling, we show that over the first 48 h of P_i limitation, metabolic flux through the N assimilation and aromatic amino acid pathways is increased. We propose that together with a shift in amino acid metabolism in the chloroplast a transient restoration of the energetic and redox state of the leaf is achieved. Correlation analysis of metabolite abundances revealed a central role for major amino acids in P_i stress, appearing to modulate partitioning of soluble sugars between amino acid and carboxylate synthesis, thereby limiting leaf biomass accumulation when external P_i is low.     

Characterization of orthophosphate-induced active cation transport in isolated liver mitochondria

The kinetics of the P_i-induced active transport of ions by isolated liver mitochondria were studied by monitoring photometrically mitochondrial volume changes. In a previous communication, these volume changes were shown to correlate quantitatively with the net uptake or release of ions. In the present study the specificity of the P_i role was further characterized. The data support the contention that cations are actively transported. Anions follow the transfer of cations to maintain electrical neutrality. The relationship of the transport system to oxidative phosphorylation was investigated by simultaneously monitoring both processes under different experimental conditions. The results of the experiments are quantitatively consistent with a model proposed for the P_i-induced active transport in isolated rat liver mitochondria. The model includes the following features. 1. P_i induces an inwardly directed, carrier-mediated active transport of cations. 2. The transport is coupled to the energy-conserving reactions of the cytochrome chain. 3. The efflux of ions accumulated in the presence of low P_i concentrations occurs by passive diffusion. 4. Net accumulation ceases when the rates of active transport and passive diffusion become equal. 5. The active transport competes with oxidative phosphorylation for a common, nonphosphorylated, high-energy intermediate.     

Expression of the Na/P<Subscript>i</Subscript>-cotransporter Type IIb in Sf9 Cells: Functional Characterization and Purification

In mammals the type IIb Na/P_i-cotransporter is expressed in various tissues such as intestine, brain, lung and testis. The type IIb cotransporter shows 51% homology with the renal type IIa Na/P_i-cotransporter, for which a detailed model of the secondary structure has emerged based on recent structure/function studies. To make the type IIb Na/P_i-cotransporter available for future structural studies, we have expressed this cotransporter in Sf9 cells. Sf9 cells were infected with recombinant baculovirus containing 6His NaPi-IIb. Infected cells expressed a polypeptide of ~90 kDa, corresponding to a partially glycosylated form of the type IIb cotransporter. Transport studies demonstrated that the type IIb protein expressed in Sf9 cells mediates transport of phosphate in a Na-dependent manner with similar kinetic characteristics (apparent K _ms for sodium and phosphate and pH dependence) as previously described. Solubilization experiments demonstrated that, in contrast to the type IIa cotransporter, the type IIb can be solubilized by nonionic detergents and that solubilized type IIb Na/P_i-cotransporter can be purified by Ni-NTA chromatography.     

Energetics of under-water swimming in Adélie penguins (Pygoscelis adeliae)

Summary The energy consumption of Adélie penguins while at rest in water (8.4 W·kg^-1 at 4°C) or swimming below the surface was determined using a 21 m long canal fitted with respiration chambers at each end. Penguins chose to swim 86% of the time at speeds recorded in nature. Cost of transport was lowest (7.9 J·kg^-1·m^-1) at 1.7–2.3 m·s^-1, corresponding to a power input of 15.8 W·kg^-1, and only 50% as high as previously reported. Assuming a muscle efficiency of 0.25, propulsion efficiency is 0.4 and overall efficiency is 0.1. Calculated food requirements vary between 1060 g krill per adult and foraging trip at the beginning of the breeding season and 2500 g at the period of highest demand, prior to crèching of the chicks.Abbreviations BMR basal metabolic rate - COT cost of transport - DEE daily energy expenditure - DF daily food - M mass - P _i power input - P _o power output - PVC polyvinyl chloride - RMR resting metabolic rate - SE standard error - STPD Standard temperature, pressure and density - VO₂ oxygen consumption - t time     

Phosphate transport in mitochondria: Past accomplishments,present problems,and future challenges

The requirement of inorganic phosphate (P_i) for oxidative phosphorylation in eukaryotic cells is fulfilled through specific P_i transport systems. The mitochondrial proton/phosphate symporter (P_ic) is a membrane-embedded protein which translocates P_i from the cytosol into the mitochondrial matrix. P_ic is responsible for the very rapid transport of most of the P_i used in ATP synthesis. During the past five years there have been advances on several fronts. Genomic and cDNA clones for yeast, bovine, rat, and human P_ic have been isolated and sequenced. Functional expression of yeast P_ic in yeast strains deficient in P_i transport and expression inEscherichia coli of a chimera protein involving P_ic and ATP synthase subunit have been accomplished. P_ic, in contrast to other members of the family of transporters involved in energy metabolism, was demonstrated to have a presequence, which optimizes the import of the precursor protein into mitochondria. Six transmembrane segments appear to be a structural feature shared between P_ic and other mitochondrial anion carriers, and recent-site directed mutagenesis studies implicate structure-functional relationships to bacteriorhodopsin. These recent advances on P_ic will be assessed in light of a more global interpretation of transport mechanism across the inner mitochondrial membrane.     

Chloride Conductance and P i Transport are Separate Functions Induced by the Expression of NaPi-1 in Xenopus Oocytes

Expression of the protein NaPi-1 in Xenopus oocytes has previously been shown to induce an outwardly rectifying Cl⁻ conductance (G_Cl), organic anion transport and Na⁺-dependent P _i -uptake. In the present study we investigated the relation between the NaPi-1 induced G_Cl and P _i -induced currents and transport. NaPi-1 expression induced P _i -transport, which was not different at 1–20 ng/oocyte NaPi-1 cRNA injection and was already maximal at 1–2 days after cRNA injection. In contrast, G_Cl was augmented at increased amounts of cRNA injection (1–20 ng/oocyte) and over a five day expression period. Subsequently all experiments were performed on oocytes injected with 20 ng/oocytes cRNA. P _i -induced currents (Ip) could be observed in NaPi-1 expressing oocytes at high concentrations of P _i (≥ 1 mm P _i ). The amplitudes of Ip correlated well with G_Cl. Ip was blocked by the Cl⁻ channel blocker NPPB, partially Na⁺-dependent and completely abolished in Cl⁻ free solution. In contrast, P _i -transport in NaPi-1 expressing oocytes was not NPPB sensitive, stronger depending on extracellular Na⁺ and weakly affected by Cl⁻ substitution. Endogenous P _i -uptake in water-injected oocytes amounted in all experiments to 30–50% of the Na⁺-dependent P _i -transport observed in NaPi-1 expressing oocytes. The properties of the endogenous P _i -uptake system (K _m for P _i > 1 mm; partial Na⁺- and Cl⁻-dependence; lack of NPPB block) were similar to the NaPi-1 induced P _i -uptake, but no Ip could be recorded at P _i -concentrations ≤3 mm. In summary, the present data suggest that Ip does not reflect charge transfer related to P _i -uptake, but a P _i -mediated modulation of G_Cl. Received: 22 October 1997/Revised: 24 March 1998