Reconstitution studies using the helical and carboxy-terminal domains of enzyme I of the phosphoenolpyruvate:sugar phosphotransferase system

Enzyme I of the bacterial phosphoenolpyruvate:sugar phosphotransferase system can be phosphorylated by PEP on an active-site histidine residue, localized to a cleft between an alpha-helical domain and an alpha/beta domain on the amino terminal half of the protein. The phosphoryl group on the active-site histidine can be passed to an active-site histidine residue of HPr. It has been proposed that the major interaction between enzyme I and HPr occurs via the alpha-helical domain of enzyme I. The isolated recombinant alpha-helical domain (residues 25-145) with approximately 80% alpha-helices as well as enzyme I deficient in that domain [EI(DeltaHD)] with approximately 50% alpha-helix content from M. capricolum were used to further elucidate the nature of the enzyme I-HPr complex. Isothermal titration calorimetry demonstrated that HPr binds to the alpha-helical domain and intact enzyme I with = 5 x 10(4) and 1.4 x 10(5) M(-)(1) at pH 7.5 and 25 degrees C, respectively, but not to EI(DeltaHD), which contains the active-site histidine of enzyme I and can be autophosphorylated by PEP. In vitro reconstitution experiments with proteins from both M. capricolum and E. coli showed that EI(DeltaHD) can donate its bound phosphoryl group to HPr in the presence of the isolated alpha-helical domain. Furthermore, M. capricolum recombinant C-terminal domain of enzyme I (EIC) was shown to reconstitute phosphotransfer activity with recombinant N-terminal domain (EIN) approximately 5% as efficiently as the HD-EI(DeltaHD) pair. Recombinant EIC strongly self-associates ( approximately 10(10) M(-)(1)) in comparison to dimerization constants of 10(5)-10(7) M(-)(1) measured for EI and EI(DeltaHD).     

Properties of the C-terminal domain of enzyme I of the Escherichia coli phosphotransferase system

The bacterial phosphoenolpyruvate (PEP):glycose phosphotransferase system (PTS) mediates uptake/phosphorylation of sugars. The transport of all PTS sugars requires Enzyme I (EI) and a phosphocarrier histidine protein of the PTS (HPr). The PTS is stringently regulated, and a potential mechanism is the monomer/dimer transition of EI, because only the dimer accepts the phosphoryl group from PEP. EI monomer consists of two major domains, at the N and C termini (EI-N and EI-C, respectively). EI-N accepts the phosphoryl group from phospho-HPr but not PEP. However, it is phosphorylated by PEP(Mg(2+)) when complemented with EI-C. Here we report that the phosphotransfer rate increases approximately 25-fold when HPr is added to a mixture of EI-N, EI-C, and PEP(Mg(2+)). A model to explain this effect is offered. Sedimentation equilibrium results show that the association constant for dimerization of EI-C monomers is 260-fold greater than the K(a) for native EI. The ligands have no detectable effect on the secondary structure of the dimer (far UV CD) but have profound effects on the tertiary structure as determined by near UV CD spectroscopy, thermal denaturation, sedimentation equilibrium and velocity, and intrinsic fluorescence of the 2 Trp residues. The binding of PEP requires Mg(2+). For example, there is no effect of PEP on the T(m), an increase of 7 degrees C in the presence of Mg(2+), and approximately 14 degrees C when both are present. Interestingly, the dissociation constants for each of the ligands from EI-C are approximately the same as the kinetic (K(m)) constants for the ligands in the complete PTS sugar phosphorylation assays.     

Transient state kinetics of enzyme IICBGlc, a glucose transporter of the phosphoenolpyruvate phosphotransferase system of Escherichia coli: equilibrium and second order rate constants for the glucose binding and phosphotransfer reactions

During translocation across the cytoplasmic membrane of Escherichia coli, glucose is phosphorylated by phospho-IIA(Glc) and Enzyme IICB(Glc), the last two proteins in the phosphotransfer sequence of the phosphoenolpyruvate:glucose phosphotransferase system. Transient state (rapid quench) methods were used to determine the second order rate constants that describe the phosphotransfer reactions (phospho-IIA(Glc) to IICB(Glc) to Glc) and also the second order rate constants for the transfer from phospho-IIA(Glc) to molecularly cloned IIB(Glc), the soluble, cytoplasmic domain of IICB(Glc). The rate constants for the forward and reverse phosphotransfer reactions between IIA(Glc) and IICB(Glc) were 3.9 x 10(6) and 0.31 x 10(6) m(-1) s(-1), respectively, and the rate constant for the physiologically irreversible reaction between [P]IICB(Glc) and Glc was 3.2 x 10(6) m(-1) s(-1). From the rate constants, the equilibrium constants for the transfer of the phospho-group from His90 of [P]IIA(Glc) to the phosphorylation site Cys of IIB(Glc) or IICB(Glc) were found to be 3.5 and 12, respectively. These equilibrium constants signify that the thiophospho-group in these proteins has a high phosphotransfer potential, similar to that of the phosphohistidinyl phosphotransferase system proteins. In these studies, preparations of IICB(Glc) were invariably found to contain endogenous, firmly bound Glc (estimated K'(D) approximately 10(-7) m). The bound Glc was kinetically competent and was rapidly phosphorylated, indicating that IICB(Glc) has a random order, Bi Bi, substituted enzyme mechanism. The equilibrium constant for the binding of Glc was deduced from differences in the statistical goodness of fit of the phosphotransfer data to the kinetic model.     

Structure of the full-length enzyme I of the phosphoenolpyruvate-dependent sugar phosphotransferase system

Enzyme I (EI) is the phosphoenolpyruvate (PEP)-protein phosphotransferase at the entry point of the PEP-dependent sugar phosphotransferase system, which catalyzes carbohydrate uptake into bacterial cells. In the first step of this pathway EI phosphorylates the heat-stable phospho carrier protein at His-15 using PEP as a phosphoryl donor in a reaction that requires EI dimerization and autophosphorylation at His-190. The structure of the full-length protein from Staphylococcus carnosus at 2.5A reveals an extensive interaction surface between two molecules in adjacent asymmetric units. Structural comparison with related domains indicates that this surface represents the biochemically relevant contact area of dimeric EI. Each monomer has an extended configuration with the phosphohistidine and heat-stable phospho carrier protein-binding domains clearly separated from the C-terminal dimerization and PEP-binding region. The large distance of more than 35A between the active site His-190 and the PEP binding site suggests that large conformational changes must occur during the process of autophosphorylation, as has been proposed for the structurally related enzyme pyruvate phosphate dikinase. Our structure for the first time offers a framework to analyze a large amount of research in the context of the full-length model.     

Effects of mutations and truncations on the kinetic behavior of IIAGlc, a phosphocarrier and regulatory protein of the phosphoenolpyruvate phosphotransferase system of Escherichia coli

IIAGlc, a component of the glucose-specific phosphoenolpyruvate:phosphotransferase system (PTS) of Escherichia coli, is important in regulating carbohydrate metabolism. In Glc uptake, the phosphotransfer sequence is: phosphoenolpyruvate --> Enzyme I --> HPr --> IIAGlc --> IICBGlc --> Glc. (HPr is the first phosphocarrier protein of the PTS.) We previously reported two classes of IIAGlc mutations that substantially decrease the P-transfer rate constants to/from IIAGlc. A mutant of His75 which adjoins the active site (His90), (H75Q), was 0.5% as active as wild-type IIAGlc in the reversible P-transfer to HPr. Two possible explanations were offered for this result: (a) the imidazole ring of His75 is required for charge delocalization and (b) H75Q disrupts the hydrogen bond network: Thr73, His75, phospho-His90. The present studies directly test the H-bond network hypothesis. Thr73 was replaced by Ser, Ala, or Val to eliminate the network. Because the rate constants for phosphotransfer to/from HPr were largely unaffected, we conclude that the H-bond network hypothesis is not correct. In the second class of mutants, proteolytic truncation of seven residues of the IIAGlc N terminus caused a 20-fold reduction in phosphotransfer to membrane-bound IICBGlc from Salmonella typhimurium. Here, we report the phosphotransfer rates between two genetically constructed N-terminal truncations of IIAGlc (Delta7 and Delta16) and the proteins IICBGlc and IIBGlc (the soluble cytoplasmic domain of IICBGlc). The truncations did not significantly affect reversible P-transfer to IIBGlc but substantially decreased the rate constants to IICBGlc in E. coli and S. typhimurium membranes. The results support the hypothesis (Wang, G., Peterkofsky, A., and Clore, G. M. (2000) J. Biol. Chem. 275, 39811-39814) that the N-terminal 18-residue domain "docks" IIAGlc to the lipid bilayer of membranes containing IICBGlc.     

Interdomain interaction and substrate coupling effects on dimerization and conformational stability of enzyme I of the Escherichia coli phosphoenolpyruvate:sugar phosphotransferase system.

The bacterial PEP:sugar phosphotransferase system couples the phosphorylation and translocation of specific sugars across the membrane. The activity of the first protein in this pathway, enzyme I (EI), is regulated by a monomer-dimer equilibrium where a Mg(2+)-dependent autophosphorylation by PEP requires the dimer. Dimerization constants for dephospho- and phospho-EI and inactive mutants EI(H189E) and EI(H189A) (in which Glu or Ala is substituted for the active site His189) have been measured under a variety of conditions by sedimentation equilibrium at pH 7.5 and 4 and 20 degrees C. Concurrently, thermal unfolding of these forms of EI has been monitored by differential scanning calorimetry and by changes in the intrinsic tryptophanyl residue fluorescence. Phosphorylated EI and EI(H189E) have 10-fold increased dimerization constants [ approximately 2 x 10(6) (M monomer)(-1)] compared to those of dephospho-EI and EI(H189A) at 20 degrees C. Dimerization is strongly promoted by 1 mM PEP with 2 mM MgCl(2) [K(A)' > or = 10(8) M(-1) at 4 or 20 degrees C], as demonstrated with EI(H189A) which cannot undergo autophosphorylation. Together, 1 mM PEP and 2 mM Mg(2+) also markedly stabilize and couple the unfolding of C- and N-terminal domains of EI(H189A), increasing the transition temperature (T(m)) for unfolding the C-terminal domain by approximately 18 degrees C and that for the N-terminal domain by approximately 9 degrees C to T(max) congruent with 63 degrees C, giving a value of K(D)' congruent with 3 microM PEP at 45 degrees C. PEP alone also promotes the dimerization of EI(H189A) but only increases T(m) approximately 5 degrees C for C-terminal domain unfolding without affecting N-terminal domain unfolding, giving an estimated value of K(D)' congruent with 0.2 mM for PEP dissociation in the absence of Mg(2+) at 45 degrees C. In contrast, the dimerization constant of phospho-EI at 20 degrees C is the same in the absence and presence of 5 mM PEP and 2 mM MgCl(2). Thus, the separation of substrate binding effects from those of phosphorylation by studies with the inactive EI(H189A) has shown that intracellular concentrations of PEP and Mg(2+) are important determinants of both the conformational stability and dimerization of dephospho-EI.     

Calorimetric and spectroscopic investigation of the interaction between the C‐terminal domain of Enzyme I and its ligands

Enzyme I initiates a series of phosphotransfer reactions during sugar uptake in the bacterial phosphotransferase system. Here, we have isolated a stable recombinant C-terminal domain of Enzyme I (EIC) of Escherichia coli and characterized its interaction with the N-terminal domain of Enzyme I (EIN) and also with various ligands. EIC can phosphorylate EIN, but their binding is transient regardless of the presence of phosphoenolpyruvate (PEP). Circular dichroism and NMR indicate that ligand binding to EIC induces changes near aromatic groups but not in the secondary structure of EIC. Binding of PEP to EIC is an endothermic reaction with the equilibrium dissociation constant (K_D) of 0.28 mM, whereas binding of the inhibitor oxalate is an exothermic reaction with K_D of 0.66 mM from calorimetry. The binding thermodynamics of EIC and PEP compared to that of Enzyme I (EI) and PEP reveals that domain–domain motion in EI can contribute as large as ∼−3.2 kcal/mol toward PEP binding.     

Identification of a phosphoenolpyruvate:fructose phosphotransferase system (fructose-1-phosphate forming) in Listeria monocytogenes.

Listeria monocytogenes is a gram-positive bacterium whose carbohydrate metabolic pathways are poorly understood. We provide evidence for an inducible phosphoenolpyruvate (PEP):fructose phosphotransferase system (PTS) in this pathogen. The system consists of enzyme I, HPr, and a fructose-specific enzyme II complex which generates fructose-1-phosphate as the cytoplasmic product of the PTS-catalyzed vectorial phosphorylation reaction. Fructose-1-phosphate kinase then converts the product of the PTS reaction to fructose-1,6-bisphosphate. HPr was shown to be phosphorylated by [32P]PEP and enzyme I as well as by [32P]ATP and a fructose-1,6-bisphosphate-activated HPr kinase like those found in other gram-positive bacteria. Enzyme I, HPr, and the enzyme II complex of the Listeria PTS exhibit enzymatic cross-reactivity with PTS enzyme constituents from Bacillus subtilis and Staphylococcus aureus.     

Genetic and biochemical characterization of the phosphoenolpyruvate:glucose/mannose phosphotransferase system of Streptococcus thermophilus

In most streptococci, glucose is transported by the phosphoenolpyruvate (PEP):glucose/mannose phosphotransferase system (PTS) via HPr and IIAB(Man), two proteins involved in regulatory mechanisms. While most strains of Streptococcus thermophilus do not or poorly metabolize glucose, compelling evidence suggests that S. thermophilus possesses the genes that encode the glucose/mannose general and specific PTS proteins. The purposes of this study were to determine (i) whether these PTS genes are expressed, (ii) whether the PTS proteins encoded by these genes are able to transfer a phosphate group from PEP to glucose/mannose PTS substrates, and (iii) whether these proteins catalyze sugar transport. The pts operon is made up of the genes encoding HPr (ptsH) and enzyme I (EI) (ptsI), which are transcribed into a 0.6-kb ptsH mRNA and a 2.3-kb ptsHI mRNA. The specific glucose/mannose PTS proteins, IIAB(Man), IIC(Man), IID(Man), and the ManO protein, are encoded by manL, manM, manN, and manO, respectively, which make up the man operon. The man operon is transcribed into a single 3.5-kb mRNA. To assess the phosphotransfer competence of these PTS proteins, in vitro PEP-dependent phosphorylation experiments were conducted with purified HPr, EI, and IIAB(Man) as well as membrane fragments containing IIC(Man) and IID(Man). These PTS components efficiently transferred a phosphate group from PEP to glucose, mannose, 2-deoxyglucose, and (to a lesser extent) fructose, which are common streptococcal glucose/mannose PTS substrates. Whole cells were unable to catalyze the uptake of mannose and 2-deoxyglucose, demonstrating the inability of the S. thermophilus PTS proteins to operate as a proficient transport system. This inability to transport mannose and 2-deoxyglucose may be due to a defective IIC domain. We propose that in S. thermophilus, the general and specific glucose/mannose PTS proteins are not involved in glucose transport but might have regulatory functions associated with the phosphotransfer properties of HPr and IIAB(Man).     

Stereochemical course of the reactions catalyzed by the bacterial phosphoenolpyruvate:glucose phosphotransferase system

The overall stereochemical course of the reactions leading to the phosphorylation of methyl alpha-D-glucopyranoside by the glucose-specific enzyme II (enzyme IIGlc) of the Escherichia coli phosphotransferase system has been investigated. With [(R)-16O,17O,18O]phosphoenolpyruvate as the phosphoryl donor and in the presence of enzyme I, HPr, and enzyme IIIGlc of the phosphotransferase system, membranes from E. coli containing enzyme IIGlc catalyzed the formation of methyl alpha-D-glucopyranoside 6-phosphate with overall inversion of the configuration at phosphorus (with respect to phosphoenolpyruvate). It has previously been shown that sequential covalent transfer of the phosphoryl group of phosphoenolpyruvate to enzyme I, to HPr, and to enzyme IIIGlc occurs before the final transfer from phospho-enzyme IIIGlc to the sugar, catalyzed by enzyme IIGlc. Because overall inversion of the configuration of the chiral phospho group of phosphoenolpyruvate implies an odd number of transfer steps, the phospho group has been transferred at least five times, and transfer from phospho-enzyme IIIGlc to the sugar must occur in two steps (or a multiple thereof). On the basis that no membrane protein other than enzyme IIGlc is directly involved in the final phospho transfer steps, our results imply that a covalent phospho-enzyme IIGlc is an intermediate during transport and phosphorylation of glucose by the E. coli phosphotransferase system.     

Opposing effects of phosphoenolpyruvate and pyruvate with Mg(2+) on the conformational stability and dimerization of phosphotransferase enzyme I from Escherichia coli

The activity of enzyme I (EI), the first protein in the bacterial PEP:sugar phosphotransferase system, is regulated by a monomer-dimer equilibrium where a Mg(2+)-dependent autophosphorylation by PEP requires the homodimer. Using inactive EI(H189A), in which alanine is substituted for the active-site His189, substrate-binding effects can be separated from those of phosphorylation. Whereas 1 mM PEP (with 2 mM Mg(2+)) strongly promotes dimerization of EI(H189A) at pH 7.5 and 20 degrees C, 5 mM pyruvate (with 2 mM Mg(2+)) has the opposite effect. A correlation between the coupling of N- and C-terminal domain unfolding, measured by differential scanning calorimetry, and the dimerization constant for EI, determined by sedimentation equilibrium, is observed. That is, when the coupling between N- and C-terminal domain unfolding produced by 0.2 or 1.0 mM PEP and 2 mM Mg(2+) is inhibited by 5 mM pyruvate, the dimerization constant for EI(H189A) decreases from > 10(8) to < 5 x 10(5) or 3 x 10(7) M(-1), respectively. Incubation of the wild-type, dephospho-enzyme I with the transition-state analog phosphonopyruvate and 2 mM Mg(2+) also increases domain coupling and the dimerization constant approximately 42-fold. With 2 mM Mg(2+) at 15-25 degrees C and pH 7.5, PEP has been found to bind to one site/monomer of EI(H189A) with K(A)' approximately 10(6) M(-1) (deltaG' = -8.05 +/- 0.05 kcal/mole and deltaH = +3.9 kcal/mole at 20 degrees C); deltaC(p) = -0.33 kcal K(-1) mole(-1). The binding of PEP to EI(H189A) is synergistic with that of Mg(2+). Thus, physiological concentrations of PEP and Mg(2+) increase, whereas pyruvate and Mg(2+) decrease the amount of dimeric, active, dephospho-enzyme I.     

Crystal Structure of Enzyme I of the Phosphoenolpyruvate Sugar Phosphotransferase System in the Dephosphorylated State

The bacterial phosphoenolpyruvate (PEP) sugar phosphotransferase system mediates sugar uptake and controls the carbon metabolism in response to carbohydrate availability. Enzyme I (EI), the first component of the phosphotransferase system, consists of an N-terminal protein binding domain (EIN) and a C-terminal PEP binding domain (EIC). EI transfers phosphate from PEP by double displacement via a histidine residue on EIN to the general phosphoryl carrier protein HPr. Here we report the 2.4 Å crystal structure of the homodimeric EI from Staphylococcus aureus. EIN consists of the helical hairpin HPr binding subdomain and the phosphorylatable βα phospho-histidine (P-His) domain. EIC folds into an (βα)₈ barrel. The dimer interface of EIC buries 1833 Ų of accessible surface per monomer and contains two Ca²⁺ binding sites per dimer. The structures of the S. aureus and Escherichia coli EI domains (Teplyakov, A., Lim, K., Zhu, P. P., Kapadia, G., Chen, C. C., Schwartz, J., Howard, A., Reddy, P. T., Peterkofsky, A., and Herzberg, O. (2006) Proc. Natl. Acad. Sci. U.S.A. 103, 16218–16223) are very similar. The orientation of the domains relative to each other, however, is different. In the present structure the P-His domain is docked to the HPr binding domain in an orientation appropriate for in-line transfer of the phosphate to the active site histidine of the acceptor HPr. In the E. coli structure the phospho-His of the P-His domain projects into the PEP binding site of EIC. In the S. aureus structure the crystallographic temperature factors are lower for the HPr binding domain in contact with the P-His domain and higher for EIC. In the E. coli structure it is the reverse.     

Functional interactions between proteins of the phosphoenolpyruvate:sugar phosphotransferase systems of Bacillus subtilis and Escherichia coli.

Proteins of the phosphoenolpyruvate:sugar phosphotransferase system (PTS) of Bacillus subtilis were overexpressed, purified to near homogeneity, and characterized. The proteins isolated include Enzyme I, HPr, the glucose-specific IIA domain of the glucose-specific Enzyme II (IIAglc), and the mannitol-specific IIA protein, IIAmtl. Site specific mutant proteins of IIAglc and HPr were also overexpressed and purified, and their properties were compared with those of the wild type proteins. These proteins and their phosphorylated derivatives were characterized with respect to their immunological cross-reactivities employing the Western blot technique and in terms of their migratory behavior during sodium dodecyl sulfate-gel electrophoresis, nondenaturing gel electrophoresis, and isoelectric focusing. The interactions between homologous and heterologous Enzymes I and HPrs, between homologous and heterologous HPrs and the IIAglc proteins, and between homologous and heterologous IIAglc proteins and IIBCscr of B. subtilis as well as IICBglc of Escherichia coli were defined and compared kinetically. The mutant HPrs and IIAglc proteins were also characterized kinetically as PTS phosphocarrier proteins and/or as inhibitors of the phosphotransferase reactions of the PTS. These studies revealed that complexation of IIAglc with the mutant form of HPr in which serine 46 was replaced by aspartate (S46D) did not increase the rate of phosphoryl transfer from phospho Enzyme I to S46D HPr more than when IIAmtl was complexed to S46D HPr. These findings do not support a role for HPr(Ser-P) in the preferential utilization of one PTS carbohydrate relative to another. Functional analyses in E. coli established that IIAglc of B. subtilis can replace IIAglc of E. coli with respect both to sugar transport and to regulation of non-PTS permeases, catabolic enzymes, and adenylate cyclase. Site-specific mutations in histidyl residues 68 and 83 (H68A and H83A) inactivated IIAglc of B. subtilis with respect to phosphoryl transfer and its various regulatory roles.     

Sugar transport by the bacterial phosphotransferase system. Characterization of the sulfhydryl groups and site-specific labeling of enzyme I

Enzyme I is the first protein of the phospho transfer sequence in the bacterial phosphoenolpyruvate:glycose phosphotransferase system. This protein exhibits a temperature-dependent monomer/dimer equilibrium. The nucleotide sequence of Escherichia coli ptsI indicates four -SH residues per subunit (Saffen, D. W., Presper, K. A., Doering, T. L., and Roseman, S. (1987) J. Biol. Chem. 262, 16241-16253). In the present experiments, the sulfhydryl groups of the E. coli enzyme were studied with various -SH-specific reagents. Titration of Enzyme I with 5,5'-dithiobis-2-nitrobenzoic acid also revealed four reacting -SH groups. The kinetics of the 5,5'-dithiobis-2-nitrobenzoic acid reaction with Enzyme I exhibit biphasic character, with pseudo-first order rate constants of 2.3 x 10(-2)/s and 2.3 x 10(-3)/s at pH 7.5, at room temperature. Fractional amplitudes associated with the rate constants were 25 +/- 5% for the fast and 75 +/- 5% for the slow rate. The "slow" rate was influenced by ligands that react with Enzyme I (the protein HPr, Mg2+, Mg2+ plus P-enolpyruvate), and also by temperature (at the temperature range where the monomer/dimer association occurs). The fractional ratio of the two rates remained at 1:3 under these conditions. Thus, under all conditions tested, two classes of -SH groups were detected, one reacting more rapidly than the other three -SH groups. Modification of the "fast" -SH group results in an active enzyme capable of forming dimer, whereas modification of the slow -SH groups results in inactive and monomeric Enzyme I. The enzyme was labeled with pyrene maleimide under conditions where only the more reactive sulfhydryl group was derivatized. Hydrolysis by trypsin followed by reverse-phase high performance liquid chromatography analysis of the peptide mixture resulted in only one fluorescent peak. This peak was not observed when the more reactive sulfhydryl residue was protected prior to pyrene maleimide labeling. Amino acid sequencing of the fluorescent peak indicated that the more reactive residue is the C-terminal amino acid residue, cysteine 575. The results provide a means for selectively labeling Enzyme I with a fluorophore at a single site while retaining full catalytic activity.     

Evidence for the evolutionary relatedness of the proteins of the bacterial phosphoenolpyruvate:sugar phosphotransferase system

The phosphoenolpyruvate:sugar phosphotransferase system (PTS) found in enteric bacteria is a complex enzyme system consisting of a non-sugar-specific phosphotransfer protein called Enzyme I, two small non-sugar-specific phosphocarrier substrates of Enzyme I, designated HPr and FPr, and at least 11 sugar-specific Enzymes II or Enzyme II-III pairs which are phosphorylated at the expense of phospho-HPr or phospho-FPr. In this communication, evidence is presented which suggests that these proteins share a common evolutionary origin and that a fructose-specific phosphotransferase may have been the primordial ancestor of them all. The evidence results from an evaluation of 1) PTS protein sequence data; 2) structural analysis of operons encoding proteins of the PTS; 3) genetic regulatory mechanisms controlling expression of these operons; 4) enzymatic characteristics of the PTS systems; 5) immunological cross reactivities of these proteins; 6) comparative studies of phosphotransferase systems from evolutionarily divergent bacteria; 7) the nature of the phosphorylated protein intermediates; 8) molecular weight comparisons among the different Enzymes II and Enzyme II-III pairs; and 9) interaction studies involving different PTS protein constituents. The evidence leads to a unifying theory concerning the evolutionary origin of the system, explains many structural, functional, and regulatory properties of the phosphotransferase system, and leads to specific predictions which should guide future research concerned with genetic, biochemical, and physiological aspects of the system.     

Stability and binding of the phosphorylated species of the N-terminal domain of enzyme I and the histidine phosphocarrier protein from the Streptomyces coelicolor phosphoenolpyruvate:sugar phosphotransferase system

The phosphotransferase system (PTS) is involved in the use of carbon sources in bacteria. It is formed by two general proteins: enzyme I (EI) and the histidine phosphocarrier (HPr), and various sugar-specific permeases. EI is formed by two domains, with the N-terminal domain (EIN) being responsible for the binding to HPr. In low-G+C Gram-positive bacteria, HPr becomes phosphorylated not only by phosphoenolpyruvate (PEP) at the active-site histidine, but also by ATP at a serine. In this work, we have characterized: (i) the stability and binding affinities between the active-site-histidine phosphorylated species of HPr and the EIN from Streptomyces coelicolor; and (ii) the stability and binding affinities of the species involving the phosphorylation at the regulatory serine of HPr(sc). Our results show that the phosphorylated active-site species of both proteins are less stable than the unphosphorylated counterparts. Conversely, the Hpr-S47D, which mimics phosphorylation at the regulatory serine, is more stable than wild-type HPr(sc) due to helical N-capping effects, as suggested by the modeled structure of the protein. Binding among the phosphorylated and unphosphorylated species is always entropically driven, but the affinity and the enthalpy vary widely.     

Subunit association of enzyme I of the Salmonella typhimurium phosphoenolpyruvate: glycose phosphotransferase system. Temperature dependence and thermodynamic properties

The bacterial phosphoenolpyruvate:glycose phosphotransferase system plays an essential role in diverse physiological phenomena. To perform these functions, the system is stringently regulated, although the underlying molecular regulatory mechanisms have not been established. A potential target for this type of regulation is the first protein in the phosphotransfer sequence, Enzyme I, which catalyzes the following reaction: P-enolpyruvate + Enzyme I Mg2+ in equilibrium phospho-I + pyruvate. We reported previously that Enzyme I from Salmonella typhimurium consists of identical subunits which associate in a temperature-dependent manner; the mode of association was found to be either monomer-dimer or isodesmic. The association reaction has now been investigated by analytical gel chromatography at 8, 11, and 23 degrees C. At each temperature, the mode of association was strictly monomer-dimer. The apparent association equilibrium constant, K'a, increased dramatically with temperature, with an enthalpy of 54.8 +/- 6.3 kcal/mol. At 23 degrees C, K'a decreased slightly when the enzyme solution contained either Mg2+ or phosphoenolpyruvate. However, when both ligands were present, i.e. under conditions where Enzyme I is phosphorylated, K'a decreased significantly (25-fold at 11 degrees C and 50-fold at 23 degrees C). These results are in accord with a model for the action of Enzyme I which involves a cycle of association and dissociation. This model has potentially important implications for regulating Enzyme I and the bacterial phosphoenolpyruvate:glycose phosphotransferase system.     

Enzyme I: the gateway to the bacterial phosphoenolpyruvate:sugar phosphotransferase system.

Regulatory aspects of the bacterial phosphoenolpyruvate (PEP):sugar phosphotransferase system (PTS) are reviewed. The structure and conformational stability of the first protein (enzyme I) of the PTS, as well as the requirement for enzyme I to dimerize for autophosphorylation by PEP in the presence of MgCl2 are discussed.     

Synthesis of HPr(Ser-P)(His-P) by enzyme I of the phosphoenolpyruvate: sugar phosphotransferase system of Streptococcus salivarius

HPr is a protein of the bacterial phosphoenolpyruvate:sugar phosphotransferase transport system (PTS). In Gram-positive bacteria, HPr can be phosphorylated on Ser(46) by HPr(Ser) kinase/phosphorylase (HPrK/P) and on His(15) by enzyme I (EI) of the PTS. In vitro studies have shown that phosphorylation on one residue greatly inhibits the second phosphorylation. However, streptococci contain significant amounts of HPr(Ser-P)(His approximately P) during exponential growth, and recent studies suggest that phosphorylation of HPr(Ser-P) by EI is involved in the recycling of HPr(Ser-P)(His approximately P). We report in this paper a study on the phosphorylation of Streptococcus salivarius HPr, HPr(Ser-P), and HPr(S46D) by EI. Our results indicate that (i) the specificity constant (k(cat)/K(m)) of EI for HPr(Ser-P) at pH 7.9 was approximately 5000-fold smaller than that observed for HPr, (ii) no metabolic intermediates were able to stimulate HPr(Ser-P) phosphorylation, (iii) the rate of HPr phosphorylation decreased at pHs below 6.5, while that of HPr(Ser-P) increased and was almost 10-fold higher at pH 6.1 than at pH 7.9, (iv) HPr(S46D), a mutated HPr alleged to mimic HPr(Ser-P), was also phosphorylated more efficiently under acidic conditions, and, lastly, (v) phosphorylation of Bacillus subtilis HPr(Ser-P) by B. subtilis EI was also stimulated at acidic pH. Our results suggest that the high levels of HPr(Ser-P)(His approximately P) in streptococci result from the combination of two factors, a high physiological concentration of HPr(Ser-P) and stimulation of HPr(Ser-P) phosphorylation by EI at acidic pH, an intracellular condition that occurs in response to the acidification of the external medium during growth of the culture.