Two systems for the uptake of phosphate in Escherichia coli.

Mutants of Escherichia coli K-12 were constructed such that each possessed one single major system for phosphate transport. A comparison of these strains showed that one of the systems (PIT) was fully constitutive, required no binding protein, and operated in spheroplasts. It permitted the complete exchange of intracellular phosphate with extracellular phosphate (or arsenate) and was completely inhibited by uncouplers. The other system, PST, was repressible by phosphate concentrations above 1 mM, required the phosphate-binding protein for full activity, and did not operate in spheroplasts. It catalyzed very little exchange between internal and external phosphate and was resistant to uncouplers. The maximal velocities attained by the two systems were approximately the same, but the affinity for phosphate in the PST system was greater by two orders of magnitude. In strains in which both systems were fully operative, the initial rates of uptake was nearly additive, and the systems appeared to interact with a common intracellular phosphate pool.     

Inorganic phosphate transport inAcinetobacter lwoffi

The transport of inorganic phosphate has been studied inAcinetobacter lwoffi JW11. During growth on excess phosphate, only one transport system was present, with an apparent K_m of 1.4 M. When cells were starved for phosphate, a second uptake system with an apparent K_m of 110 nM was also synthesized. The two transport systems could be distinguished by differing sensitivities to the phosphate analogs arsenate and 2-aminoethylphosphonate. Both systems were inhibited by carbonylcyanidem-chlorophenylhydrazone, and to a lesser extent by Na azide. The high-affinity transport system was inactivated by osmotic shock treatment and by spheroplast formation. Preliminary evidence for a phosphate-binding protein in the osmotic shock fluid is presented. The isolation of a mutant constitutive for the high-affinity transport system is described.     

Phosphate transport in Pseudomonas aeruginosa. Involvement of a periplasmic phosphate-binding protein

A binding protein for inorganic phosphate was purified to apparent homogeneity from the shock fluids of phosphate-limited Pseudomonas aeruginosa. The purified protein bound one molecule of phosphate per molecule of binding protein with an average Kd of 0.34 microM. Arsenate, pyrophosphate and polyphosphates up to 15 units long could inhibit the binding of phosphate to the binding protein, although organic phosphates, such as glucose 6-phosphate, glycerol 3-phosphate and adenosine 5'-monophosphate could not. Mutants lacking the phosphate-binding protein were isolated and shown to be deficient in phosphate transport compared with wild-type cells. Two kinetically distinct systems for phosphate uptake could be observed in wild-type cells, with apparent Km values of 0.46 +/- 0.10 microM (high affinity) and 12.0 +/- 1.6 microM (low affinity). In contrast, only a single low-affinity transport system was observable in mutants lacking the binding protein (Km apparent = 19.3 +/- 1.4 microM Pi), suggesting the involvement of the binding protein in the inducible high-affinity phosphate-uptake system of P. aeruginosa.     

Conditions leading to secretion of a normally periplasmic protein in Escherichia coli.

The phosphate-binding protein (PhoS) is a periplasmic protein which is part of the high-affinity phosphate transport system of Escherichia coli. Hyperproduction of PhoS in strains carrying a multicopy plasmid containing phoS led to partial secretion of the protein. By 6 h after transfer to phosphate-limiting medium, about 13% of the total newly synthesized PhoS was secreted to the medium. Kinetic studies demonstrated that this secretion consists of newly synthesized PhoS. This secretion occurs in PhoS-hyperproducer strains but not in a PhoS-overproducer strain. Another type of secretion concerning periplasmic PhoS was observed in both PhoS-hyperproducer and PhoS-overproducer strains. This mode of secretion depended upon the addition of phosphate to cells previously grown in phosphate-limiting medium.     

Reconstitution of binding protein dependent ribose transport in spheroplasts derived from a binding protein negative escherichia coli K12 mutant and from salmonella typhimurium

Highly purified ribose-binding protein from Escherichia coli has been used to reconstitute a binding-protein-dependent ribose transport in spheroplasts derived from a binding-protein-deficient mutant of E coli K 12, and in spheroplasts derived from Salmonella typhimurium. The cross-species reconstitution was nearly as efficient as the reconstitution of the E coli strain from which the binding protein was derived. Antibody raised against the ribose binding protein completely prevented reconstitution, whereas it had no effect on whole cells. The reconstitution procedure has been improved by generating spheroplasts from cells grown in a rich medium and by reducing the background uptake in spheroplasts through a special washing procedure. Rapid purification of ribose binding protein by high pressure liquid chromatography is also described.     

Reconstitution of maltose transport in Escherichia coli: conditions affecting import of maltose-binding protein into the periplasm of calcium-treated cells.

The reconstitution of active transport by the Ca2+ -induced import of exogenous binding protein was studied in detail in whole cells of a malE deletion mutant lacking the periplasmic maltose-binding protein. A linear increase in reconstitution efficiency was observed by increasing the Ca2+ - concentration in the reconstitution mixture up to 400 mM. A sharp pH optimum around pH 7.5 was measured for reconstitution. Reconstitution efficiency was highest at 0 degree C and decreased sharply with increasing temperature. The time necessary for optimal reconstitution at 0 degree C and 250 mM Ca2+ was about 1 min. The competence for reconstitution was highest in exponentially growing cultures with cell densities up to 1 X 10(9)/ml and declined when the cells entered the stationary-growth phase. The apparent Km for maltose uptake was the same as that of wild-type cells (1 to 2 microM). Vmax at saturating maltose-binding protein concentration was 125 pmol per min per 7.5 X 10(7) cells (30% of the wild-type activity). The concentration of maltose-binding protein required for half-maximal reconstitution was about 1 mM. The reconstitution procedure appears to be generally applicable. Thus, galactose transport in Escherichia coli could also be reconstituted by its respective binding protein. Maltose transport in E. coli was restored by maltose-binding protein isolated from Salmonella typhimurium. Finally, in S. typhimurium, histidine transport was reconstituted by the addition of shock fluid containing histidine-binding protein to a hisJ deletion mutant lacking histidine-binding protein. The method is fast and general enough to be used as a screening procedure to distinguish between transport mutants in which only the binding protein is affected and those in which additional transport components are affected.     

Ca2+-induced permeabilization of the Escherichia coli outer membrane: comparison of transformation and reconstitution of binding-protein-dependent transport.

Ca2+ treatment renders the outer membrane of Escherichia coli reversibly permeable for macromolecules. We investigated whether Ca2+-induced uptake of exogenous protein into the periplasm occurs by mechanisms similar to Ca2+-induced uptake of DNA into the cytoplasm during transformation. Protein import through the outer membrane was monitored by measuring reconstitution of maltose transport after the addition of shock fluid containing maltose-binding protein. DNA import through the outer and inner membrane was measured by determining the efficiency of transformation with plasmid DNA. Both processes were stimulated by increasing Ca2+ concentrations up to 400 mM. Plasmolysis was essential for a high efficiency; reconstitution and transformation could be stimulated 5- and 40-fold, respectively, by a high concentration of sucrose (400 mM) in cells incubated with a suboptimal Ca2+ concentration (50 mM). The same divalent cations that promote import of DNA (Ca2+, Ba2+, Sr2+, Mg2+, and Ni2+) also induced import of protein. Ca2+ alone was found to be inefficient in promoting reconstitution; successive treatment with phosphate and Ca2+ ions was essential. Transformation also was observed in the absence of phosphate, but could be stimulated by pretreatment with phosphate. The optimal phosphate concentrations were 100 mM and 1 to 10 mM for reconstitution and transformation, respectively. Heat shock, in which the cells are rapidly transferred from 0 to 42 degrees C, affected the two processes differently. Incubation of cells at 0 degrees C in Ca2+ alone allows rapid entry of protein, but not of DNA. Transformation was observed only when exogenous DNA was still present during the heat shock. Shock fluid containing maltose-binding protein inhibited transformation (with 6 microgram of DNA per ml, half-maximal inhibition occurred at around 300 microgram of shock fluid per ml). DNA inhibited reconstitution (with 5 microgram of shock fluid per ml, half-maximal inhibition occurred at around 3 mg of DNA per ml).     

The aerobactin iron uptake system in enteropathogenic Escherichia coli: evidence for an extinct transposon

Abstract It has previously been demonstrated that the precursor form of the phosphate-binding protein (pre-PhoS) is accumulated in both the cytoplasmic membrane and the cytoplasm under conditions of phosphate-binding protein (PhoS) hyperproduction in Escherichia coli [11]. In this study, the trypsin accessibility of these 2 pre-PhoS pools has been investigated in spheroplasts. The results demonstrate that the membrane-associated pre-PhoS is not accessible to trypsin, and thus has not been translocated. The sensitivity to trypsin of mature PhoS, membrane-associated pre-PhoS and cytoplasmic pre-PhoS was compared. The results suggest a difference in conformation between membrane-associated and cytoplasmic pre-PhoS since the former is more trypsin-sensitive than the latter. Mature PhoS is resistant to trypsin. The significance of these results with regard to the export mechanism for periplasmic proteins is discussed.     

Lipopolysaccharide transport to the bacterial outer membrane in spheroplasts

The mechanism of lipopolysaccharide (LPS) transport in Gram-negative bacteria from the inner membrane to the outer membrane is largely unknown. Here, we investigated the possibility that LPS transport proceeds via a soluble intermediate associated with a periplasmic chaperone analogous to the Lol-dependent transport mechanism of lipoproteins. Whereas newly synthesized lipoproteins could be released from spheroplasts of Escherichia coli upon addition of a periplasmic extract containing LolA, de novo synthesized LPS was not released. We demonstrate that LPS synthesized de novo in spheroplasts co-fractionated with the outer membranes and that this co-fractionation was dependent on the presence in the spheroplasts of a functional MsbA protein, the protein responsible for the flip-flop of LPS across the inner membrane. The outer membrane localization of the LPS was confirmed by its modification by the outer membrane enzyme CrcA (PagP). We conclude that a substantial amount of LPS was translocated to the outer membrane in spheroplasts, suggesting that transport proceeds via contact sites between the two membranes. In contrast to LPS, de novo synthesized phospholipids were not transported to the outer membrane in spheroplasts. Apparently, LPS and phospholipids have different requirements for their transport to the outer membrane.     

Active accumulation of tetracycline by Escherichia coli

1. At low concentrations of tetracycline (10mug/ml) net accumulation of the drug by Escherichia coli cells ceased after 7-10min. 2. At higher concentrations of tetracycline (>30mug/ml) the period of net accumulation of the drug was significantly extended. 3. The efflux of tetracycline from E. coli cells transferred from medium containing 10mug of tetracycline/ml to drug-free medium was a rapid temperature-dependent process and was accelerated by 2,4-dinitrophenol. 4. As the concentration of tetracycline in the preloading phase was increased, the rate of subsequent efflux of the drug progressively declined. The efflux of drug from cells preloaded in medium containing 200mug of tetracycline/ml was negligible, although efflux was readily provoked by 2,4-dinitrophenol, by N-ethylmaleimide or by omission of glucose from the medium. 5. The initial rate of uptake of tetracycline by E. coli cells was linearly proportional to the concentration of tetracycline in the medium up to the maximum concentration of drug obtainable under the experimental conditions used (400mug/ml, 0.83mm). 6. Although N-ethylmaleimide strongly inhibited the accumulation of tetracycline by E. coli, no evidence was obtained for the direct involvement of thiol groups in the transport process. It was concluded that N-ethylmaleimide inhibited accumulation by interruption of the energy supply of the cells. 7. Osmotic shock of E. coli cells did not significantly affect the influx of tetracycline, but promoted both efflux of tetracycline and cell lysis in cells treated with a high concentration of tetracycline. 8. A study of the distribution of tetracycline among the subcellular fractions of penicillin-induced spheroplasts preincubated with various concentrations of tetracycline indicated that 60-70% of the accumulated tetracycline was in the high-speed supernatant fraction. Sephadex chromatography showed that the tetracycline of this fraction was present as the free drug. Sephadex chromatography of a detergent extract of the membrane fraction, however, indicated that a significant proportion of the tetracycline radioactivity of this fraction was apparently bound to some macromolecular component. 9. Cellulose phosphate paper chromatography of cold-acid extracts of spheroplasts preloaded with tetracycline indicated that the accumulated drug was chemically unchanged. 10. Membrane preparations isolated from osmotically lysed penicillin-induced spheroplasts showed a temperature-dependent binding of tetracycline that was not energy-dependent and was not inhibited by N-ethylmaleimide. The binding process was stimulated by omitting Mg(2+) from the medium, but conversely was profoundly inhibited by EDTA. 11. The relevance of these findings to the probable mechanism of active tetracycline accumulation by E. coli is discussed.     

In vivo functional assay of a recombinant aquaporin in Pichia pastoris

The water channel protein PvTIP3;1 (alpha-TIP) is a member of the major intrinsic protein (MIP) membrane channel family. We overexpressed this eukaryotic aquaporin in the methylotrophic yeast Pichia pastoris, and immunogold labeling of cellular cryosections showed that the protein accumulated in the plasma membrane, as well as vacuolar and other intracellular membranes. We then developed an in vivo functional assay for water channel activity that measures the change in optical absorbance of spheroplasts following an osmotic shock. Spheroplasts of wild-type P. pastoris displayed a linear relationship between absorbance and osmotic shock level. However, spheroplasts of P. pastoris expressing PvTIP3;1 showed a break in this linear relationship corresponding to hypo-osmotically induced lysis. It is the difference between control and transformed spheroplasts under conditions of hypo-osmotic shock that forms the basis of our aquaporin activity assay. The aquaporin inhibitor mercury chloride blocked water channel activity but had no effect on wild-type yeast. Osmotically shocked yeast cells were affected only slightly by expression of the Escherichia coli glycerol channel GlpF, which belongs to the MIP family but is a weak water channel. The important role that aquaporins play in human physiology has led to a growing interest in their potential as drug targets for treatment of hypertension and congestive heart failure, as well as other fluid overload states. The simplicity of this assay that is specific for water channel activity should enable rapid screening for compounds that modulate water channel activity.     

Phosphate uptake in the yeast Candida tropicalis: purification of phosphate-binding protein and investigations about its role in phosphate uptake

The purification of a phosphate-binding protein (P_iBP₂) by immunoadsorption is described. The entire anti phosphate-binding protein 2 antibodies as well as the Fab fragments obtained from these antibodies inhibit P_i uptake by whole cells. The inhibition is a mixed type of inhibition (V _m and K _m are affected). These results should be regarded as a possible involvement of phosphate-binding protein 2 in P_i uptake. The binding of ¹²⁵I-labelled fragments prepared from anti phosphate-binding protein 2 antibodies to whole cells, to shocked cells and to protoplasts has been investigated. The results confirm the release of phosphate-binding protein by osmotic shock and during protoplast formation. From these findings, a cell-wall localisation, near the cell surface of the phosphate-binding protein should be proposed.Abbreviations P_i inorganic phosphate - P_iBP phosphate-binding protein - Tris Tris (hydroxymethyl)-aminoethane - MES (2(N-Morpholino) ethanesulfonic acid - BSA bovine serum albumin - EDTA ethylene diamine tetraacetic acid, disodium salt - PMSF phenylmethyl sulfonyl fluoride - SDS sodium dodecyl sulfate - Fab fragments, fragment antigen binding     

Transport of Glycerol by Pseudomonas aeruginosa

In Pseudomonas aeruginosa, the transport of glycerol was shown to be genetically controlled and to be dependent on induction by glycerol. Accumulation of (14)C-glycerol was almost completely absent in uninduced cells and in a transport-negative mutant. Kinetic studies with induced cells suggested that glycerol may be transported by two systems with different affinities for glycerol. Osmotically shocked cells did not transport glycerol, and the supernatant fluid from shocked cells contained glycerol-binding activity demonstrable by equilibrium dialysis. The binding protein was not glycerol kinase. Binding activity was absent in shock fluids from the transport-negative mutant and from uninduced cells. The glycerol-binding protein was partially purified by precipitation with ammonium sulfate. Mild heat treatment completely eliminated the binding activity of shock fluid and of the partially purified protein. Sodium azide and N-ethylmaleimide inhibited both transport by whole cells and binding of glycerol by shock fluid. It is concluded that transport of glycerol by P. aeruginosa involves a binding protein responsible for recognition of glycerol and may occur by facilitated diffusion or active transport. A requirement for energy has not been demonstrated.     

tonB-independent ferrichrome-mediated iron transport in Escherichia coli spheroplasts.

Although a functional tonB gene product was required for ferrichrome-mediated iron transport in whole cells of Escherichia coli K-12, such transport did not require the tonB+ function in spheroplasts. We suggest that in spheroplasts ferrichrome has direct access to the cytoplasmic membrane and that this is reflected in tonB-independent accumulation of ferrichrome iron. Therefore, the tonB gene product does not function in the translocation of ferrichrome iron across the inner membrane.     

Periplasmic enzymes in Bdellovibrio bacteriovorus and Bdellovibrio stolpii.

When cells of either Bdellovibrio bacteriovorus 109J or Bdellovibrio stolpii UKi2 were subjected to osmotic shock by treatment with sucrose-EDTA and MgCl2 solutions, only trace amounts of proteins or enzyme activities were released into the shock fluid. In contrast, when nongrowing cells were converted to motile, osmotically stable, peptidoglycan-free spheroplasts by penicillin treatment, numerous proteins were released into the suspending fluid. For both species, this suspending fluid contained substantial levels of 5'-nucleotidase, purine phosphorylase, and deoxyribose-phosphate aldolase. Penicillin treatment also released aminoendopeptidase N from B. bacteriovorus, but not from B. stolpii. Penicillin treatment did not cause release of cytoplasmic enzymes such as malate dehydrogenase. The data indicated that bdellovibrios possess periplasmic enzymes or peripheral enzymes associated with the cell wall complex. During intraperiplasmic bdellovibrio growth, periplasmic and cytoplasmic enzymes of the Escherichia coli substrate cell were not released upon formation of the spherical bdelloplast during bdellovibrio penetration. Most of the E. coli enzymes were retained within the bdelloplast until later in the growth cycle, when they became inactivated or released into the suspending buffer or both.     

Reconstitution of binding protein-dependent ribose transport in spheroplasts of Escherichia coli K-12.

Purified Escherichia coli K-12 ribose binding protein was used to reconstitute the high affinity ribose transport system in spheroplasts derived from ribose-induced cells. It was not possible to reconstitute ribose transport in spheroplasts derived from uninduced cells or from transport-negative mutant strains, suggesting that one or more additional inducible components are required for binding protein-dependent ribose transport. It was possible to reconstitute transport in a ribokinase-deficient mutant which constitutively transports but does not utilize ribose.     

Localization of Phosphoglucose Isomerase in Escherichia coli and Its Relation to the Induction of the Hexose Phosphate Transport System

The localization of phosphoglucose isomerase (PGI) was studied in relation to the induction of hexose phosphate uptake in Escherichia coli. The uptake system is induced only by extracellular glucose-6-phosphate (G6P); there is no induction by intracellular G6P. Fructose-6-phosphate (F6P) is an indirect inducer, and isomerization of F6P to G6P must occur before induction. PGI has been considered to be an internal enzyme; therefore, uptake of F6P by noninduced cells and leakage of the G6P formed would be required for induction. In this study, it was concluded that part of the PGI activity is located in the cell surface because: (i) uninduced, intact cells are able to convert F6P to G6P, whereas the activity of G6P dehydrogenase is not detectable; (ii) when cells are subjected to osmotic shock, about 10% of the PGI activity is found in the shock fluid; and (iii) sorbitol-6-phosphate (S6P) inhibits both PGI activity of whole cells and the induction of hexose phosphate transport system by F6P. S6P was not taken by intact cells. The data indicate that the isomerization of F6P to G6P can take place on the cell surface, and this explains the indirect induction of hexose phosphate transport by F6P.     

Overproduction of acetate kinase activates the phosphate regulon in the absence of the phoR and phoM functions in Escherichia coli.

A DNA fragment of Escherichia coli cloned on pBR322 elevated the production of alkaline phosphatase and phosphate-binding protein in a phoR phoM strain. Nucleotide sequence analysis and enzyme assays revealed that the DNA fragment contained the ackA gene, which codes for acetate kinase. A high gene dosage of ackA was needed to induce the production of alkaline phosphatase and phosphate-binding protein in this strain. Overexpression of ackA elevated the intracellular ATP concentration, an effect that might be related to activation of the phosphate regulon in the phoR phoM strain.     

Mutagenesis of residue betaArg-246 in the phosphate-binding subdomain of catalytic sites of Escherichia coli F1-ATPase

Residues responsible for phosphate binding in F(1)F(0)-ATP synthase catalytic sites are of significant interest because phosphate binding is believed linked to proton gradient-driven subunit rotation. From x-ray structures, a phosphate-binding subdomain is evident in catalytic sites, with conserved betaArg-246 in a suitable position to bind phosphate. Mutations betaR246Q, betaR246K, and betaR246A in Escherichia coli were found to impair oxidative phosphorylation and to reduce ATPase activity of purified F(1) by 100-fold. In contrast to wild type, ATPase of mutants was not inhibited by MgADP-fluoroaluminate or MgADP-fluoroscandium, showing the Arg side chain is required for wild-type transition state formation. Whereas 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole (NBD-Cl) inhibited wild-type ATPase essentially completely, ATPase in mutants was inhibited maximally by approximately 50%, although reaction still occurred at residue betaTyr-297, proximal to betaArg-246 in the phosphate-binding pocket. Inhibition characteristics supported the conclusion that NBD-Cl reacts in betaE (empty) catalytic sites, as shown previously by x-ray structure analysis. Phosphate protected against NBD-Cl inhibition in wild type but not in mutants. The results show that phosphate can bind in the betaE catalytic site of E. coli F(1) and that betaArg-246 is an important phosphate-binding residue.     

Structure-function relationships in a bacterial DING protein

A recombinant DING protein from Pseudomonas fluorescens has been previously shown to have a phosphate-binding site, and to be mitogenic for human cells. Here we report the three-dimensional structure of the protein, confirming a close similarity to the "Venus flytrap" structure seen in other human and bacterial phosphate-binding proteins. Site-directed mutagenesis confirms the role of a key residue involved in phosphate binding, and that the mitogenic activity is not dependent on this property. Deletion of one of the two hinged domains that constitute the Venus flytrap also eliminates phosphate binding whilst enhancing mitogenic activity.