Mutational analysis of putative phosphate- and proton-binding sites in the Saccharomyces cerevisiae Pho84 phosphate:H(+) transceptor and its effect on signalling to the PKA and PHO pathways

In Saccharomyces cerevisiae, the Pho84 phosphate transporter acts as the main provider of phosphate to the cell using a proton symport mechanism, but also mediates rapid activation of the PKA (protein kinase A) pathway. These two features led to recognition of Pho84 as a transceptor. Although the physiological role of Pho84 has been studied in depth, the mechanisms underlying the transport and sensor functions are unclear. To obtain more insight into the structure-function relationships of Pho84, we have rationally designed and analysed site-directed mutants. Using a three-dimensional model of Pho84 created on the basis of the GlpT permease, complemented with multiple sequence alignments, we selected Arg(168) and Lys(492), and Asp(178), Asp(358) and Glu(473) as residues potentially involved in phosphate or proton binding respectively, during transport. We found that Asp(358) (helix 7) and Lys(492) (helix 11) are critical for the transport function, and might be part of the putative substrate-binding pocket of Pho84. Moreover, we show that alleles mutated in the putative proton-binding site Asp(358) are still capable of strongly activating PKA pathway targets, despite their severely reduced transport activity. This indicates that signalling does not require transport and suggests that mutagenesis of amino acid residues involved in binding of the co-transported ion may constitute a promising general approach to separate the transport and signalling functions in transceptors.     

Regulation of cation-coupled high-affinity phosphate uptake in the yeast Saccharomyces cerevisiae

Studies of the high-affinity phosphate transporters in the yeast Saccharomyces cerevisiae using mutant strains lacking either the Pho84 or the Pho89 permease revealed that the transporters are differentially regulated. Although both genes are induced by phosphate starvation, activation of the Pho89 transporter precedes that of the Pho84 transporter early in the growth phase in a way which may possibly reflect a fine tuning of the phosphate uptake process relative to the availability of external phosphate.     

Structure and function of the GTP binding protein Gtr1 and its role in phosphate transport in Saccharomyces cerevisiae

The Pho84 high-affinity phosphate permease is the primary phosphate transporter in the yeast Saccharomyces cerevisiae under phosphate-limiting conditions. The soluble G protein, Gtr1, has previously been suggested to be involved in the derepressible Pho84 phosphate uptake function. This idea was based on a displayed deletion phenotype of Deltagtr1 similar to the Deltapho84 phenotype. As of yet, the mode of interaction has not been described. The consequences of a deletion of gtr1 on in vivo Pho84 expression, trafficking and activity, and extracellular phosphatase activity were analyzed in strains synthesizing either Pho84-green fluorescent protein or Pho84-myc chimeras. The studies revealed a delayed response in Pho84-mediated phosphate uptake and extracellular phosphatase activity under phosphate-limiting conditions. EPR spectroscopic studies verified that the N-terminal G binding domain (residues 1-185) harbors the nucleotide responsive elements. In contrast, the spectra obtained for the C-terminal part (residues 186-310) displayed no evidence of conformational changes upon GTP addition.     

Characterization of purified, reconstituted site-directed cysteine mutants of the lactose permease of Escherichia coli

lac permease mutated at each of the 8 cysteinyl residues in the molecule was solubilized from the membrane, purified, and reconstituted into proteoliposomes. The transport activity of proteoliposomes reconstituted with each mutant permease relative to the wild-type is virtually identical with that reported for intact cells and/or right-side-out membrane vesicles. Moreover, a double mutant containing Ser in place of both Cys148 and Cys154 exhibits significant ability to catalyze active lactose transport. The results provide strong confirmation for the contention that cysteinyl residues in lac permease do not play an important role in the transport mechanism. The effect of sulfhydryl oxidant 5-hydroxy-2-methyl-1,4-naphthoquinone on lactose transport in proteoliposomes reconstituted with wild-type or mutant permeases was also investigated, and the results indicate that inactivation is probably due to formation of a covalent adduct with Cys148 and/or Cys154 rather than disulfide formation. Thus, it seems unlikely that sulfhydryl-disulfide interconversion functions to regulate permease activity.     

Mutational analysis of conserved glutamic acids of Pho89, a Saccharomyces cerevisiae high-affinity inorganic phosphate:Na+ symporter

In Saccharomyces cerevisiae, the high-affinity phosphate transport system comprises the Pho84 and Pho89 permeases. The Pho89 permease catalyzes import of inorganic phosphate in a symport manner by utilizing Na⁺ ions as co-solute. We have addressed the functional importance of two glutamic acid residues at positions 55 and 491. Both residues are highly conserved amongst members of the inorganic phosphate transporter (PiT) family, which might be an indication of functional importance. Moreover, both residues have been shown to be of critical importance in the hPit2 transporter. We have created site-directed mutations of both E55 and E491 to lysine and glutamine. We observed that in all four cases there is a dramatic impact on the transport activity, and thus it seems that they indeed are of functional importance. Following these observations, we addressed the membrane topology of this protein by using several prediction programs. TOPCONS predicts a 7-5 transmembrane segment organization, which is the most concise topology as compared to the hPiT2 transporter. By understanding the functionality of these residues, we are able to correlate the Pho89 topology to that of the hPiT2, and can now further analyze residues which might play a role in the transport activity.     

Purified lac permease and cytochrome o oxidase are functional as monomers

Purified lac permease, the 46.5-kDa product of the lac Y gene that catalyzes lactose/H+ symport, or purified cytochrome o, a terminal oxidase of the Escherichia coli respiratory chain composed of four subunits with a composite molecular mass of 140 kDa, was reconstituted into proteoliposomes individually or in combination. The preparations were then examined by freeze-fracture electron microscopy employing conventional platinum/carbon replicas or by means of a new technique using thin tantalum replicas. In nonenergized proteoliposomes, both proteins appear to reconstitute as monomers based on (i) the variation of intramembrane particle density with protein concentration; (ii) the ratio of particles corresponding to each protein in proteoliposomes reconstituted with a known ratio of permease to oxidase; and (iii) the dimensions of the particles observed in tantalum replicas. The intramembrane particle diameters in tantalum replicas are about 20-25% smaller than those observed in conventional platinum/carbon replicas, indicating that the dimensions of the particles revealed with tantalum more accurately reflect the sizes of lac permease and cytochrome o. The diameters and heights of the permease and cytochrome o in tantalum replicas are 5.1 nm X 2.8 nm and 7.4 nm X 4.2 nm, respectively. Furthermore, a higher percentage of lac permease molecules exhibits a notch or cleft in tantalum replicas relative to platinum/carbon replicas. Importantly, the initial rate of lactose/H+ symport in proteoliposomes varies linearly with the ratio of lac permease to phospholipid, and no change is observed in either the size or distribution of lac permease molecules when the proteoliposomes are energized. The results taken as a whole provide a strong indication that both lac permease and cytochrome o reconstitute into proteoliposomes as monomers, that the permease does not dimerize in the presence of the H+ electrochemical gradient, and that both molecules are completely functional as monomers.     

Inorganic phosphate is sensed by specific phosphate carriers and acts in concert with glucose as a nutrient signal for activation of the protein kinase A pathway in the yeast Saccharomyces cerevisiae

Yeast cells starved for inorganic phosphate on a glucose-containing medium arrest growth and enter the resting phase G0. We show that re-addition of phosphate rapidly affects well known protein kinase A targets: trehalase activation, trehalose mobilization, loss of heat resistance, repression of STRE-controlled genes and induction of ribosomal protein genes. Phosphate-induced activation of trehalase is independent of protein synthesis and of an increase in ATP. It is dependent on the presence of glucose, which can be detected independently by the G-protein coupled receptor Gpr1 and by the glucose-phosphorylation dependent system. Addition of phosphate does not trigger a cAMP signal. Despite this, lowering of protein kinase A activity by mutations in the TPK genes strongly reduces trehalase activation. Inactivation of phosphate transport by deletion of PHO84 abolishes phosphate signalling at standard concentrations, arguing against the existence of a transport-independent receptor. The non-metabolizable phosphate analogue arsenate also triggered signalling. Constitutive expression of the Pho84, Pho87, Pho89, Pho90 and Pho91 phosphate carriers indicated pronounced differences in their transport and signalling capacities in phosphate-starved cells. Pho90 and Pho91 sustained highest phosphate transport but did not sustain trehalase activation. Pho84 sustained both transport and rapid signalling, whereas Pho87 was poor in transport but positive for signalling. Pho89 displayed very low phosphate transport and was negative for signalling. Although the results confirmed that rapid signalling is independent of growth recovery, long-term mobilization of trehalose was much better correlated with growth recovery than with trehalase activation. These results demonstrate that phosphate acts as a nutrient signal for activation of the protein kinase A pathway in yeast in a glucose-dependent way and they indicate that the Pho84 and Pho87 carriers act as specific phosphate sensors for rapid phosphate signalling.     

Reconstitution of the binding protein-dependent galactose transport of Salmonella typhimurium in proteoliposomes.

Binding protein-dependent transport systems mediate the accumulation of diverse substrates in bacteria. The binding protein-dependent galactose transport of Salmonella typhimurium has been reconstituted in proteoliposomes. The proteoliposomes were made with proteins solubilized and renatured from inclusion bodies produced by a bacterial strain containing a plasmid with the mgl (methylgalactose permease) operon of Salmonella typhimurium. Galactose transport is dependent both on the addition of the purified galactose binding protein to the transport assay, and on ATP. The interaction between the liganded galactose binding protein and proteoliposomes displays Michaelis type kinetics with a Km of around 15 microM. Galactose transport is coupled to ATP hydrolysis with a stoichiometry (ATP/galactose) of 2.5:1. Galactose transport in proteoliposomes is not significantly inhibited by the uncoupler carbonylcyanide m-chlorophenylhydrazone, but is inhibited by 0.5 mM vanadate. The present reconstitution of galactose transport in proteoliposomes suggests that the MglA, MglC and MglE proteins have been solubilized and renatured in an active form from the inclusion bodies of the mgl hyperproducing strain.     

Uptake of Selenite by Saccharomyces cerevisiae Involves the High and Low Affinity Orthophosphate Transporters

Although the general cytotoxicity of selenite is well established, the mechanism by which this compound crosses cellular membranes is still unknown. Here, we show that in Saccharomyces cerevisiae, the transport system used opportunistically by selenite depends on the phosphate concentration in the growth medium. Both the high and low affinity phosphate transporters are involved in selenite uptake. When cells are grown at low P_i concentrations, the high affinity phosphate transporter Pho84p is the major contributor to selenite uptake. When phosphate is abundant, selenite is internalized through the low affinity P_i transporters (Pho87p, Pho90p, and Pho91p). Accordingly, inactivation of the high affinity phosphate transporter Pho84p results in increased resistance to selenite and reduced uptake in low P_i medium, whereas deletion of SPL2, a negative regulator of low affinity phosphate uptake, results in exacerbated sensitivity to selenite. Measurements of the kinetic parameters for selenite and phosphate uptake demonstrate that there is a competition between phosphate and selenite ions for both P_i transport systems. In addition, our results indicate that Pho84p is very selective for phosphate as compared with selenite, whereas the low affinity transporters discriminate less efficiently between the two ions. The properties of phosphate and selenite transport enable us to propose an explanation to the paradoxical increase of selenite toxicity when phosphate concentration in the growth medium is raised above 1 mm.     

A membrane protein based biosensor: use of a phosphate--H+ symporter membrane protein (Pho84) in the sensing of phosphate ions

A label free biosensor for direct detection of inorganic phosphate based on potential-step capacitance measurements has been developed. The high-affinity Pho84 plasma membrane phosphate/proton symporter of Saccharomyces cerevisiae was used as a sensing element. Heterologously expressed and purified Pho84 protein was immobilized on a self-assembled monolayer (SAM) on a capacitance electrode. Changes in capacitance were recorded upon exposure to phosphate compared to the control substance, phosphate analogue methylphosphonate. Hence, even without the explicit use of lipid membranes, the Pho84 membrane protein could retain its capacity of selective substrate binding, with a phosphate detection limit in the range of the apparent in vivo K(m). A linear increase in capacitance was monitored in the phosphate concentration range of 5-25 μM. The analytical response of the capacitive biosensor is in agreement with that the transporter undergoes significant conformational changes upon exposure to inorganic phosphate, while exposure to the analogue only causes minor responses.     

The SPX domain of the yeast low‐affinity phosphate transporter Pho90 regulates transport activity

Yeast has two phosphate‐uptake systems that complement each other: the high‐affinity transporters (Pho84 and Pho89) are active under phosphate starvation, whereas Pho87 and Pho90 are low‐affinity transporters that function when phosphate is abundant. Here, we report new regulatory functions of the amino‐terminal SPX domain of Pho87 and Pho90. By studying truncated versions of Pho87 and Pho90, we show that the SPX domain limits the phosphate‐uptake velocity, suppresses phosphate efflux and affects the regulation of the phosphate signal transduction pathway. Furthermore, split‐ubiquitin assays and co‐immunoprecipitation suggest that the SPX domain of both Pho90 and Pho87 interacts physically with the regulatory protein Spl2. This work suggests that the SPX domain inhibits low‐affinity phosphate transport through a physical interaction with Spl2.     

Homodimeric mitochondrial phosphate transport protein. Transient subunit/subunit contact site between the transport relevant transmembrane helices A

The three Cys of the yeast (Saccharomyces cerevisiae) mitochondrial phosphate transport protein (PTP) subunit were replaced with Ser. The seven mutants (single, double, and complete Cys replacements) were expressed in yeast, and the homodimeric mutant PTPs were purified from the mitochondria and reconstituted. The pH gradient-dependent net phosphate (Pi) transport uptake rates (initial conditions: 1 mM [Pi]e, pHe 6.80; 0 mM [Pi]i, pHi 8.07) catalyzed by these reconstituted mutants are similar to those of the wild-type protein and range from 15 to 80 micromol Pi/min mg PTP protein. Aerobic media inhibit only the Pi uptake rates catalyzed by PTPs with the conserved (yeast and bovine) Cys28. This inhibition in the proteoliposomes is 84-95% and can be completely reversed by dithiothreitol. Transport by the wild type as well as by all mutant proteins with Cys28 is more than 90% inhibited by mersalyl. Transport catalyzed by mutant proteins with only Cys300 or only Cys134 is less sensitive, and that catalyzed by the no Cys mutant shows 40% inhibition by mersalyl. When dithiothreitol is removed from purified single Cys mutant proteins, only the mutant protein with Cys28 appears as a homodimer in a nonreducing SDS polyacrylamide gel. Thus, the function relevant transmembrane helix A, with Cys 28 about equidistant from the two inner membrane surfaces, is in close contact with parts of transmembrane helix A of the other subunit in the functional homodimeric PTP. The results identify for the first time not only a transmembrane helix contact site between the two subunits of a homodimeric mitochondrial transport protein but also a contact site that if locked into position blocks transport. The results are related to two available secondary transporter structures (lactose permease, glycerol-3-phosphate transporter) as well as to a low resolution projection structure and a high resolution structure of monomers of inhibitor ADP/ATP carrier complexes.     

Structural modeling of dual-affinity purified Pho84 phosphate transporter

The phosphate transporter Pho84 of Saccharomyces cerevisiae is predicted to contain 12 transmembrane (TM) regions, divided into two partially duplicated parts of 6 TM segments. The three-dimensional (3D) organization of the Pho84 protein has not yet been determined. However, the 3D crystal structure of the Escherichia coli MFS glycerol-3-phosphate/phosphate antiporter, GlpT, and lactose transporter, LacY, has recently been determined. On the basis of extensive prediction and fold recognition analyses (at the MetaServer), GlpT was proposed as the best structural template on which the arrangement of TM segments of the Pho84 transporter was fit, using the comparative structural modeling program MODELLER. To initiate an evaluation of the appropriateness of the Pho84 model, we have performed two direct tests by targeting spin labels to putative TM segments 8 and 12. Electron paramagnetic resonance spectroscopy was then applied on purified and spin labeled Pho84. The line shape from labels located at both positions is consistent with the structural environment predicted by the template-generated model, thus supporting the model.     

Isolation and functional reconstitution of soluble melibiose permease from Escherichia coli

By use of techniques described recently for lac permease [Roepe, P.D., & Kaback, H.R. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 6087], the melibiose permease from Escherichia coli, another polytopic integral plasma membrane protein, has been purified in a metastable soluble form after overexpression of the melB gene via the T7 RNA polymerase system. As demonstrated with lac permease, soluble melibiose permease is dissociated from the membrane with 5.0 M urea and appears to remain soluble in phosphate buffer at neutral pH after removal of urea by dialysis, although the protein aggregates in a time- and concentration-dependent fashion. Moreover, soluble melibiose permease behaves as a monomer during purification by size exclusion chromatography in the presence of urea. Circular dichroism of purified soluble melibiose permease reveals that the protein is highly helical in potassium phosphate buffer and that secondary structure is disrupted in 5.0 M urea. Finally, purified melibiose permease can be reconstituted into proteoliposomes, and the preparations catalyze membrane potential driven H+/melibiose or Na+/methyl 1-thio-beta,D-galactopyranoside symport. The results provide further support for the notion that hydrophobic transmembrane proteins may be able to assume a nondenatured conformation in aqueous solution and extend the implication that the approach described may represent a general method for rapid isolation and reconstitution of this class of membrane proteins.     

Characterization of the Pho89 phosphate transporter by functional hyperexpression in Saccharomyces cerevisiae

The Na(+)-coupled, high-affinity Pho89 plasma membrane phosphate transporter in Saccharomyces cerevisiae has so far been difficult to study because of its low activity and special properties. In this study, we have used a pho84Deltapho87Deltapho90Deltapho91Delta quadruple deletion strain of S. cerevisiae devoid of all transporter genes specific for inorganic phosphate, except for PHO89, to functionally characterize Pho89 under conditions where its expression is hyperstimulated. Under these conditions, the Pho89 protein is strongly upregulated and is the sole high-capacity phosphate transporter sustaining cellular acquisition of inorganic phosphate. Even if Pho89 is synthesized in cells grown at pH 4.5-8.0, the transporter is functionally active under alkaline conditions only, with a K(m) value reflecting high-affinity properties of the transporter and with a transport rate about 100-fold higher than that of the protein in a wild-type strain. Even under these hyperexpressive conditions, Pho89 is unable to sense and signal extracellular phosphate levels. In cells grown at pH 8.0, Pho89-mediated phosphate uptake at alkaline pH is cation-dependent with a strong activation by Na(+) ions and sensitivity to carbonyl cyanide m-chlorophenylhydrazone. The contribution of H(+)- and Na(+)-coupled phosphate transport systems in wild-type cells grown at different pH values was quantified. The contribution of the Na(+)-coupled transport system to the total cellular phosphate uptake activity increases progressively with increasing pH.     

Characterization of site-directed mutants in the lac permease of Escherichia coli. 1. Replacement of histidine residues

Wild-type lac permease from Escherichia coli and two site-directed mutant permeases containing Arg in place of His35 and His39 or His322 were purified and reconstituted into proteoliposomes. H35-39R permease is indistinguishable from wild type with regard to all modes of translocation. In contrast, purified, reconstituted permease with Arg in place of His322 is defective in active transport, efflux, equilibrium exchange, and counterflow but catalyzes downhill influx of lactose without concomitant H+ translocation. Although permease with Arg in place of His205 was thought to be devoid of activity [Padan, E., Sarkar, H. K., Viitanen, P. V., Poonian, M. S., & Kaback, H. R. (1985) Proc. Natl. Acad. Sci. U.S.A. 82, 6765], sequencing of lac Y in pH205R reveals the presence of two additional mutations in the 5' end of the gene, and replacement of this portion of lac Y with a restriction fragment from the wild-type gene yields permease with normal activity. Permeases with Asn, Gln, or Lys in place of His322, like H322R permease, catalyze downhill influx of lactose without H+ translocation but are unable to catalyze active transport, equilibrium exchange, or counterflow. Unlike H322R permease, however, the latter mutants catalyze efflux at rates comparable to that of wild-type permease, although the reaction does not occur in symport with H+. Finally, as evidenced by flow dialysis and photoaffinity labeling experiments, replacement of His322 appears to cause a marked decrease in the affinity of the permease for substrate. The results confirm and extend the contention that His322 is the only His residue in the permease involved in lactose/H+ symport and that an imidazole moiety at position 322 is obligatory.(ABSTRACT TRUNCATED AT 250 WORDS)     

Measurement of proton pump activity of the thermophilic bacterium PS3 and Nitrobacter agilis at the cytochrome oxidase level using total membrane and heptyl thioglucoside

It is possible to prepare liposomal vesicles by solubilization of total bacterial membranes with n-heptyl beta-D-thioglucoside followed by reconstitution into proteoliposomes by a freeze-thaw-sonication procedure with soybean phospholipids. The resulting proteoliposomes from total membrane fraction of sufficiently aerated cells of the thermophilic bacterium PS3 containing cytochrome aa3 showed a reasonable H+ pumping activity upon addition of reduced cytochrome c. On the other hand, the proteoliposomes reconstituted from air-limited PS3 cells containing cytochrome o and those from Nitrobacter agilis cells containing cytochrome aa3 did not show H+ pumping upon addition of reduced cytochrome c, although the vesicles showed "respiratory control"; 3-4-fold stimulation of oxygen consumption took place upon addition of an uncoupler. In proteoliposomes prepared from PS3 membranes by this method, H+-translocating ATPase (F0 X F1) was successfully reconstituted as well, suggesting that this method has wide applicability for investigation of enzymes catalyzing transmembrane processes.     

Basic amino acid transport in plasma membrane vesicles of Penicillium chrysogenum.

The characteristics of the basic amino acid permease (system VI) of the filamentous fungus Penicillium chrysogenum were studied in plasma membranes fused with liposomes containing the beef heart mitochondrial cytochrome c oxidase. In the presence of reduced cytochrome c, the hybrid membranes accumulated the basic amino acids arginine and lysine. Inhibition studies with analogs revealed a narrow substrate specificity. Within the external pH range of 5.5 to 7.5, the transmembrane electrical potential (delta psi) functions as the main driving force for uphill transport of arginine, although a low level of uptake was observed when only a transmembrane pH gradient was present. It is concluded that the basic amino acid permease is a H+ symporter. Quantitative analysis of the steady-state levels of arginine uptake in relation to the proton motive force suggests a H+-arginine symport stoichiometry of one to one. Efflux studies demonstrated that the basic amino acid permease functions in a reversible manner.