Kinetics and subunit interaction of the mannitol-specific enzyme II of the Escherichia coli phosphoenolpyruvate-dependent phosphotransferase system

Domain complementation studies reveal residues critical for the activity of the mannitol permease from Escherichia coli

This paper presents domain complementation studies in the mannitol transporter, EIImtl, from Escherichia coli. EIImtl is responsible for the transport and concomitant phosphorylation of mannitol over the cytoplasmic membrane. By using tryptophan-less EIImtl as a basis, each of the four phenylalanines located in the cytoplasmic loop between putative transmembrane helices II and III in the membrane-embedded C domain were replaced by tryptophan, yielding the mutants W97, W114, W126, and W133. Except for W97, these single-tryptophan mutants exhibited a high, wild-type-like, binding affinity for mannitol. Of the four mutants, only W114 showed a high mannitol phosphorylation activity. EIImtl is functional as a dimer and the effect of these mutations on the oligomeric activity was investigated via heterodimer formation (C/C domain complementation studies). The low phosphorylation activities of W126 and W133 could be increased 7-28 fold by forming heterodimers with either the C domain of W97 (IICmtlW97) or the inactive EIImtl mutant G196D. W126 and W133, on the other hand, did not complement each other. This study points towards a role of positions 97, 126 and 133 in the oligomeric activation of EIImtl. The involvement of specific residue positions in the oligomeric functioning of a sugar-translocating EII protein has not been presented before.

Correlation between growth rates, EIIACrr phosphorylation, and intracellular cyclic AMP levels in Escherichia coli K-12

In Escherichia coli K-12, components of the phosphoenolpyruvate-dependent phosphotransferase systems (PTSs) represent a signal transduction system involved in the global control of carbon catabolism through inducer exclusion mediated by phosphoenolpyruvate-dependent protein kinase enzyme IIA(Crr) (EIIA(Crr)) (= EIIA(Glc)) and catabolite repression mediated by the global regulator cyclic AMP (cAMP)-cAMP receptor protein (CRP). We measured in a systematic way the relation between cellular growth rates and the key parameters of catabolite repression, i.e., the phosphorylated EIIA(Crr) (EIIA(Crr) approximately P) level and the cAMP level, using in vitro and in vivo assays. Different growth rates were obtained by using either various carbon sources or by growing the cells with limited concentrations of glucose, sucrose, and mannitol in continuous bioreactor experiments. The ratio of EIIA(Crr) to EIIA(Crr) approximately P and the intracellular cAMP concentrations, deduced from the activity of a cAMP-CRP-dependent promoter, correlated well with specific growth rates between 0.3 h(-1) and 0.7 h(-1), corresponding to generation times of about 138 and 60 min, respectively. Below and above this range, these parameters were increasingly uncoupled from the growth rate, which perhaps indicates an increasing role executed by other global control systems, in particular the stringent-relaxed response system.

The oligomeric state and stability of the mannitol transporter, EnzymeII(mtl), from Escherichia coli: a fluorescence correlation spectroscopy study

Numerous membrane proteins function as oligomers both at the structural and functional levels. The mannitol transporter from Escherichia coli, EnzymeII(mtl), is a member of the phosphoenolpyruvate-dependent phosphotransferase system. During the transport cycle, mannitol is phosphorylated and released into the cytoplasm as mannitol-1-phosphate. Several studies have shown that EII(mtl) functions as an oligomeric species. However, the oligomerization number and stability of the oligomeric complex during different steps of the catalytic cycle, e.g., substrate binding and/or phosphorylation of the carrier, is still under discussion. In this paper, we have addressed the oligomeric state and stability of EII(mtl) using fluorescence correlation spectroscopy. A functional double-cysteine mutant was site-specifically labeled with either Alexa Fluor 488 or Alexa Fluor 633. The subunit exchange of these two batches of proteins was followed in time during different steps of the catalytic cycle. The most important conclusions are that (1) in a detergent-solubilized state, EII(mtl) is functional as a very stable dimer; (2) the stability of the complex can be manipulated by changing the intermicellar attractive forces between PEG-based detergent micelles; (3) substrate binding destabilizes the complex whereas phosphorylation increases the stability; and (4) substrate binding to the phosphorylated species partly antagonizes the stabilizing effect.

Dependency of sugar transport and phosphorylation by the phosphoenolpyruvate-dependent phosphotransferase system on membranous phosphatidylethanolamine in Escherichia coli: studies with a pssA mutant lacking phosphatidylserine synthase

An isogenic pair of Escherichia coli strains lacking ( pssA) and possessing (wild-type) the enzyme phosphatidylserine synthase was used to estimate the effects of the total lack of phosphatidylethanolamine (PE), the major phospholipid in E. coli membranes, on the activities of several sugar permeases (enzymes II) of the phosphoenolpyruvate:sugar phosphotransferase system (PTS). The mutant exhibits greatly elevated levels of phosphatidylglycerol (PG), a lipid that has been reported to stimulate the in vitro activities of several PTS permeases. The activities, thermal stabilities, and detergent sensitivities of three PTS permeases, the glucose enzyme II (II(Glc)), the mannose enzyme II (II(Man)) and the mannitol enzyme II (II(Mtl)), were characterized. Western blot analyses revealed that the protein levels of II(Glc) were not appreciably altered by the loss of PE. In the pssA mutant, II(Glc) and II(Man) activities were depressed both in vivo and in vitro, with the in vivo transport activities being depressed much more than the in vitro phosphorylation activities. II(Mtl) also exhibited depressed transport activity in vivo but showed normal phosphorylation activities in vitro. II(Man) and II(Glc) exhibited greater thermal lability in the pssA mutant membranes than in the wild-type membranes, but II(Mtl) showed enhanced thermal stability. All three enzymes were activated by exposure to TritonX100 (0.4%) or deoxycholate (0.2%) and inhibited by SDS (0.1%), but II(Mtl) was the least affected. II(Man) and, to a lesser degree, II(Glc) were more sensitive to detergent treatments in the pssA mutant membranes than in the wild-type membranes while II(Mtl) showed no differential effect. The results suggest that all three PTS permeases exhibit strong phospholipid dependencies for transport activity in vivo but much weaker and differential dependencies for phosphorylation activities in vitro, with II(Man) exhibiting the greatest and II(Mtl) the least dependency. The effects of lipid composition on thermal sensitivities and detergent activation responses paralleled the effects on in vitro phosphorylation activities. These results together with those previously published suggest that, while the in vivo transport activities of all PTS enzymes II require an appropriate anionic to zwitterionic phospholipid balance, the in vitro phosphorylation activities of these same enzymes show much weaker and differential dependencies. Alteration of the phospholipid composition of the membrane thus allows functional dissection of transport from the phosphorylation activities of PTS enzyme complexes.

Dependency of sugar transport and phosphorylation by the phosphoenolpyruvate-dependent phosphotransferase system on membranous phosphatidyl glycerol in Escherichia coli: studies with a pgsA mutant lacking phosphatidyl glycerophosphate synthase

It has been reported that phosphatidyl glycerol (PG) is specifically required for the in vitro activities of the hexose-phosphorylating Enzymes II of the Escherichia coli phosphoenolpyruvate-dependent sugar transporting phosphotransferase system (PTS). We have examined this possibility by measuring the properties of a null pgsA mutant that lacks detectable PG. The mutant showed lower in vitro phosphorylation activities towards several sugars when both PEP-dependent and sugar-phosphate-dependent [14C]sugar phosphorylation reactions were measured. The order of dependency on PG for the different enzymes II was: IIMannose > IIGlucose > IIFructose > IIMannitol. Nonsedimentable (40000 rpm for 2 h) Enzymes II exhibited a greater dependency on PG than pelletable Enzymes II. Western blot analyses showed that the glucose Enzyme II is present in normal amounts. Transport and fermentation measurements revealed diminished activities for all Enzymes II. Thermal stability of all of these enzymes except the mannitol-specific Enzyme II was significantly decreased by the pgsA mutation, and sensitivity to detergent treatments was enhanced. Sugar transport proved to be the most sensitive indicator of proper Enzyme II-phospholipid association. Our results show that PG stimulates but is not required for Enzyme II function in E. coli.

Phosphoenolpyruvate:carbohydrate phosphotransferase systems of bacteria

Numerous gram-negative and gram-positive bacteria take up carbohydrates through the phosphoenolpyruvate (PEP):carbohydrate phosphotransferase system (PTS). This system transports and phosphorylates carbohydrates at the expense of PEP and is the subject of this review. The PTS consists of two general proteins, enzyme I and HPr, and a number of carbohydrate-specific enzymes, the enzymes II. PTS proteins are phosphoproteins in which the phospho group is attached to either a histidine residue or, in a number of cases, a cysteine residue. After phosphorylation of enzyme I by PEP, the phospho group is transferred to HPr. The enzymes II are required for the transport of the carbohydrates across the membrane and the transfer of the phospho group from phospho-HPr to the carbohydrates. Biochemical, structural, and molecular genetic studies have shown that the various enzymes II have the same basic structure. Each enzyme II consists of domains for specific functions, e.g., binding of the carbohydrate or phosphorylation. Each enzyme II complex can consist of one to four different polypeptides. The enzymes II can be placed into at least four classes on the basis of sequence similarity. The genetics of the PTS is complex, and the expression of PTS proteins is intricately regulated because of the central roles of these proteins in nutrient acquisition. In addition to classical induction-repression mechanisms involving repressor and activator proteins, other types of regulation, such as antitermination, have been observed in some PTSs. Apart from their role in carbohydrate transport, PTS proteins are involved in chemotaxis toward PTS carbohydrates. Furthermore, the IIAGlc protein, part of the glucose-specific PTS, is a central regulatory protein which in its nonphosphorylated form can bind to and inhibit several non-PTS uptake systems and thus prevent entry of inducers. In its phosphorylated form, P-IIAGlc is involved in the activation of adenylate cyclase and thus in the regulation of gene expression. By sensing the presence of PTS carbohydrates in the medium and adjusting the phosphorylation state of IIAGlc, cells can adapt quickly to changing conditions in the environment. In gram-positive bacteria, it has been demonstrated that HPr can be phosphorylated by ATP on a serine residue and this modification may perform a regulatory function.

Phosphoenolpyruvate-dependent mannitol phosphotransferase system of Escherichia coli: overexpression, purification, and characterization of the enzymatically active C-terminal domain of enzyme IImtl equivalent to enzyme IIImtl

The extreme C-terminus (Ser-490 to Lys-637) of the Escherichia coli EIImtl was subcloned to test structural and mechanistic proposals about the existence of an EIII-like domain in this enzyme. Oligonucleotide-directed mutagenesis was used to produce a unique NcoI restriction site and, at the same time, to change Ser-490 into methionine in a flexible region in front of the proposed EIII-like domain. The 16-kDa C-terminal domain (CI) was overexpressed in Escherichia coli, purified, and analyzed in vitro for catalytic activity in the presence of an EIImtl mutated at its first phosphorylation site, His-554 (EII-H554A). The results presented show that this domain can be expressed as a structurally stable, enzymatically active entity which is able to restore the PEP-dependent phosphorylation activity of the mutant EIImtl-H554A to 25% of wild-type levels. To demonstrate the EIII activity of the CI domain in a more direct way, we also substituted it for EIIImtl in the Staphylococcus carnosus system. The CI domain was active in transferring the phosphoryl group to Staph. carnosus EII; however, it was 6.5 times less active compared to Staph. carnosus EIIImtl itself. EIIImtl from Staph. carnosus, on the other hand, was able to substitute for the isolated C-terminal domain in the E. coli mannitol phosphorylation assay; however, it appeared to be 2 or 3 times less effective.

Details of mannitol transport in Escherichia coli elucidated by site-specific mutagenesis and complementation of phosphorylation site mutants of the phosphoenolpyruvate-dependent mannitol-specific phosphotransferase system

The mannitol transport protein (EIImtl) carries out translocation with concomitant phosphorylation of mannitol from the periplasm to the cytoplasm, at the expense of phosphoenolpyruvate (PEP). The phosphoryl group which is needed for this group translocation is sequentially transferred from PEP via two phosphorylation sites, located exclusively on the C-terminal cytoplasmic domain, to mannitol. Oligonucleotide-directed mutagenesis was used to investigate the precise role of these sites in phosphoryl group transfer, by producing specific amino acid substitutions. The first phosphorylation site, His-554 (P1), was replaced by Ala, which renders the EII-H554A completely inactive in PEP-dependent mannitol phosphorylation, but not in mannitol/mannitol 1-phosphate exchange. The P2 site mutant, EII-C384S, was inactive both in the mannitol phosphorylation reaction and in the exchange reaction, due to replacement of the essential Cys-384 by Ser. Although EII-H554A and EII-C384S were both catalytically inactive in the PEP-dependent phosphorylation, EII-C384S was able to restore up to 55% of the wild-type mannitol phosphorylation activity with the EII-H554A mutant, indicating a direct phosphotransfer between two subunits. These phosphorylation data together with the data obtained from mannitol/mannitol phosphate exchange kinetics, after mixing EII-H554A and EII-C384S, indicated the formation of functionally stable heterodimers, which consist of an EII-H554A and an EII-C384S monomer.

Regulated high-level expression of the mannitol permease of the phosphoenolpyruvate-dependent sugar phosphotransferase system in Escherichia coli

The structural gene (mtlA) of the Escherichia coli phosphoenolpyruvate-dependent mannitol-transport protein (EIImtl) and its upstream promoter region (Pmtl) were subcloned approximately 150 base pairs downstream of a lambda PR promoter on a multicopy mutagenesis/expression vector and used to transform a mutant (MtlA-) E. coli strain. Induction at 42 degrees C led to 50 to 100-fold overproduction of EIImtl (5-10 mg/g of cell wet weight) relative to mannitol-induced levels in a wild-type (Mtl+) strain. Most of the overproduced protein was sequestered as an inactive form in inclusion bodies and cytoplasmic membranous structures. The protein could be extracted in an active form by rupturing the cells with lysozyme and sonication or with a passage through a French pressure cell and incubating the inclusion bodies and membranous structures with detergent (Lubrol PX or deoxycholate) in the presence of Q or S Sepharose ion-exchange resin for several hours. This procedure resulted in a 20- to 25-fold overproduction of active EIImtl compared with mannitol-induced wild-type levels.

Molecular cloning of the C-terminal domain of Escherichia coli D-mannitol permease: expression, phosphorylation, and complementation with C-terminal permease deletion proteins

We have subcloned a portion of the Escherichia coli mtlA gene encoding the hydrophilic, C-terminal domain of the mannitol-specific enzyme II (mannitol permease; molecular mass, 68 kilodaltons [kDa]) of the phosphoenolpyruvate-dependent carbohydrate phosphotransferase system. This mtlA fragment, encoding residues 379 to 637 (residue 637 = C terminus), was cloned in frame into the expression vector pCQV2 immediately downstream from the lambda pr promoter of the vector, which also encodes a temperature-sensitive lambda repressor. E. coli cells carrying a chromosomal deletion in mtlA (strain LGS322) and harboring this recombinant plasmid, pDW1, expressed a 28-kDa protein cross-reacting with antipermease antibody when grown at 42 degrees C but not when grown at 32 degrees C. This protein was relatively stable and could be phosphorylated in vitro by the general phospho-carrier protein of the phosphotransferase system, phospho-HPr. Thus, this fragment of the permease, when expressed in the absence of the hydrophobic, membrane-bound N-terminal domain, can apparently fold into a conformation resembling that of the C-terminal domain of the intact permease. When transformed into LGS322 cells harboring plasmid pGJ9-delta 137, which encodes a C-terminally truncated and inactive permease (residues 1 to ca. 480; molecular mass, 51 kDa), pDW1 conferred a mannitol-positive phenotype to this strain when grown at 42 degrees C but not when grown at 32 degrees C. This strain also exhibited phosphoenolpyruvate-dependent mannitol phosphorylation activity only when grown at the higher temperature. In contrast, pDW1 could not complement a plasmid encoding the complementary N-terminal part of the permease (residues 1 to 377). The pathway of phosphorylation of mannitol by the combined protein products of pGJ9-delta 137 and pDPW1 was also investigated by using N-ethylmaleimide to inactivate the second phosphorylation sites of these permease fragments (proposed to be Cys-384). These results are discussed with respect to the domain structure of the permease and its mechanism of transport and phosphorylation.

Deletion mutants of the Escherichia coli K-12 mannitol permease: dissection of transport-phosphorylation, phospho-exchange, and mannitol-binding activities

We have constructed a series of deletion mutations of the cloned Escherichia coli K-12 mtlA gene, which encodes the mannitol-specific enzyme II of the phosphoenolpyruvate (PEP)-dependent carbohydrate phosphotransferase system. This membrane-bound permease consists of 637 amino acid residues and is responsible for the concomitant transport and phosphorylation of D-mannitol in E. coli. Deletions into the 3' end of mtlA were constructed by exonuclease III digestion. Restriction mapping of the resultant plasmids identified several classes of deletions that lacked approximately 5% to more than 75% of the gene. Immunoblotting experiments revealed that many of these plasmids expressed proteins within the size range predicted by the restriction analyses, and all of these proteins were membrane localized, which demonstrated that none of the C-terminal half of the permease is required for membrane insertion. Functional analyses of the deletion proteins, expressed in an E. coli strain deleted for the chromosomal copy of mtlA, showed that all but one of the strains containing confirmed deletions were inactive in transport and PEP-dependent phosphorylation of mannitol, but deletions removing up to at least 117 amino acid residues from the C terminus of the permease were still active in catalyzing phospho exchange between mannitol 1-phosphate and mannitol. A deletion protein that lacked 240 residues from the C terminus of the permease was inactive in phospho exchange but still bound mannitol with high affinity. These experiments localize sites important for transport and PEP-dependent phosphorylation to the extreme C terminus of the mannitol permease, sites important for phospho exchange to between residues 377 and 519, and sites necessary for mannitol binding to the N-terminal 60% of the molecule. The results are discussed with respect to the fact that the mannitol permease consists of structurally independent N- and C-terminal domains.

Bacterial phosphoenolpyruvate-dependent phosphotransferase system: mannitol-specific EII contains two phosphoryl binding sites per monomer and one high-affinity mannitol binding site per dimer

The amino acid composition and sequence of EIIMtl is known [Lee, C. A., & Saier, M. H., Jr. (1983) J. Biol. Chem. 258, 10761-10767]. This information was combined, in the present study, with quantitative amino acid analysis to determine the molar concentration of the enzyme. The stoichiometry of phosphoryl group incorporation was then determined by phosphorylation of enzyme II from [14C]-phosphoenolpyruvate (pyruvate burst procedure). The native, reduced enzyme incorporated two phosphoryl groups per monomer. Both phosphoryl groups were shown to be transferred to mannitol. Oxidation or N-ethylmaleimide (NEM) labeling of Cys-384 resulted in incorporation of only one phosphoryl group per monomer, which was unable to be transferred to mannitol. The number of mannitol binding sites on enzyme II was determined by centrifugation using Amicon Centricon microconcentrators. The reduced unphosphorylated enzyme contained one high-affinity binding site (KD = 0.1 microM) per dimer and a second site with a KD in the micromolar range. Oxidation or NEM labeling did not change the number of binding sites.

Enzyme II of the Escherichia coli phosphoenolpyruvate-dependent phosphotransferase system: protein-protein and protein-phospholipid interactions

The mannitol-specific enzyme II (EII), purified free of phospholipid, exhibits a concentration dependence in its specific activity with P-HPr and mannitol as the donor and acceptor substrates, respectively. This concentration dependence, previously observed only in the case of mannitol----mannitol phosphate exchange reaction, indicates that an oligomeric form of the enzyme is responsible for catalyzing the phosphorylation reaction (P-HPr + mannitol----mannitol-P + HPr) as well as the exchange reaction. Kinetic analysis revealed that the monomeric enzyme has a much lower specific activity than the associated species. The specific activity can be increased by raising the steady-state level of phosphorylation of EII and also by adding phospholipid, demonstrating that phosphorylation and the binding of phospholipid facilitate the association process. Kinetic measurements and fluorescence energy transfer measurements demonstrate a strong preference of EII for phospholipids with specific head group and fatty acid composition.

Subunit interactions of the Escherichia coli mannitol permease: correlation with enzymic activities

A fraction of the phosphorylated form of the Escherichia coli mannitol permease (enzyme IIMtl) of the sugar phosphotransferase system can be extracted from the membrane in a dimeric form [Roossien, F.F., & Robillard, G.T. (1984) Biochemistry 23, 5682-5685]. Using E. coli minicells in which this protein can be specifically labeled with [35S]methionine, we show in this paper that part of the unphosphorylated form of enzyme IIMtl can also be extracted from the membrane as a dimer. We further demonstrate that both phosphoenolpyruvate-dependent phosphorylation of the permease and conditions promoting turnover of the enzyme decrease the amount of extractable dimer. Thus, the dimer of these forms of the enzyme appears to be less stable than that of the unmodified form, at least in detergent solution. In contrast, inorganic phosphate, which activates the permease-catalyzed phospho exchange between mannitol 1-phosphate and mannitol ("transphosphorylation"), stabilizes the dimer. These results support the hypothesis that the mannitol permease dimer is more active in transphosphorylation than the monomer. Treatment of minicell membranes with oxidizing agents produced heat-stable, high molecular weight aggregates of the permease on dodecyl sulfate gels, but no heat-stable dimer could be detected. The nonionic detergent Lubrol PX decreased the amount of dimer extractable at 30 degrees C with a concomitant increase in the monomeric form. These results suggest that the dimer depends predominantly on hydrophobic interactions for its stability and is not covalently cross-linked in that form by oxidizing agents.

Dimeric enzyme IImtl of the E. coli phosphoenolpyruvate-dependent phosphotransferase system. Cross-linking studies with bifunctional sulfhydryl reagents

The occurrence of intermolecular dithiols on EIImtl has been studied with a number of thiol-specific cross-linking reagents. The reaction of EIImtl with bifunctional maleimide derivatives inactivates the enzyme. At the same time the enzyme is irreversibly cross-linked to a dimeric species. Under optimal conditions 50% of the protein is cross-linked upon reaction with the dimaleimides. The enzyme is also cross-linked under oxidizing conditions in the presence of CuCl2, presumably by oxidizing an intermolecular dithiol to a disulfide. This oxidation can be reversed by the addition of the reducing agent dithiothreitol. The reaction of phosphorylated EIImtl with the same sulfhydryl-specific bifunctional reagents does not lead to any cross-linked product. The results are discussed in terms of the association state of the purified protein and the distribution of its thiol groups.

The phosphoenolpyruvate-dependent fructose-specific phosphotransferase system in Rhodopseudomonas sphaeroides. Energetics of the phosphoryl group transfer from phosphoenolpyruvate to fructose

Energy coupling to fructose transport in Rhodopseudomonas sphaeroides is achieved by phosphorylation of the membrane-spanning fructose-specific carrier protein, EFruII. The phosphoryl group of phosphoenolpyruvate is transferred to EFruII via the cytoplasmic component SF (soluble factor). The standard free enthalpy of hydrolysis of the two phosphorylated proteins has been estimated from isotope exchange measurements in chemical equilibrium. The delta G degrees for SF-P is -60.5 kJ/mol. The standard free enthalpy for hydrolysis of EII-P is -37.9 kJ/mol, but -45.2 kJ/mol when SF is still complexed to it, as in the overall reaction. Therefore the standard free enthalpy of hydrolysis of SF X EII-P is 70% of the standard free enthalpy of hydrolysis of P-enolpyruvate. The measurements reveal two regulation sites in the system. First, the phosphorylation of SF is inhibited by pyruvate when the concentration ratio of pyruvate/P-enolpyruvate becomes too high. Second, a low concentration of internal fructose prevents the phosphorylation of the carrier by the internal fructose-1-P pool when the concentration of the latter becomes too high or the phosphorylation rate by P-enolpyruvate too slow. Furthermore comparison of the isotope exchange and the overall phosphotransferase reaction kinetics leads to the conclusion that binding of fructose to the carrier is a slow step relative to the phosphoryl group transfer from EFruII to fructose.

The bacterial phosphotransferase system: kinetic characterization of the glucose, mannitol, glucitol, and N-acetylglucosamine systems

The kinetic mechanisms by which the glucose, glucitol, N-acetylglucosamine, and mannitol enzymes II catalyze sugar phosphorylation have been investigated in vitro. Lineweaver-Burk analyses indicate that the glucose and glucitol enzymes II catalyze sugar phosphorylation by a sequential mechanism when the two substrates are phospho-enzyme III and sugar. The N-acetylglucosamine and mannitol enzymes II, which do not function with an enzyme III, catalyze sugar phosphorylation by a ping-pong mechanism when the two substrates are phospho-HPr and sugar. These results, as well as previously published kinetic characterizations, suggest a common kinetic mechanism for all enzymes II of the system. It is suggested that all enzymes II and enzyme II-III pairs arose from a single (fused) gene product containing two sites of phosphorylation and that phosphoryl transfer from the second phosphorylation site to sugar can only occur when the enzyme II-III pair is present in the associated state.

The phosphoenolpyruvate-dependent fructose-specific phosphotransferase system in Rhodopseudomonas sphaeroides. Mechanism for transfer of the phosphoryl group from phosphoenolpyruvate to fructose

The phosphoenolpyruvate-dependent fructose-specific phosphotransferase system in Rhodopseudomonas sphaeroides is a membrane-bound complex of two enzymes, an integral membrane protein EII and a soluble factor SF. In media of high ionic strength the binding constant of SF to the membranes is 55 nM. Phosphorylation of SF, the first step in the reaction sequence, has no influence on the binding. The second step is the transfer of the phosphoryl group from SF to EII. The physical existence of both phosphorylated SF and EII is demonstrated and it is shown that the phosphoryl group is donated to the next species in the reaction sequence. The molecular mass of SF is 110 kDa. EII is almost completely extracted from the membrane as a dimer. The molecular mass of the monomer is 55 kDa. Both SF and EII possess thiols that are essential for catalysis. The thiol on EII is protected against inactivation by N-ethylmaleimide in the phosphorylated state. Kinetic experiments show that the binding site for fructose on EII is induced by phosphorylation of EII ('ping-pong' mechanism). The affinity constants of the phosphotransferase complex for phosphoenolpyruvate and fructose at infinite concentration of the other substrate are 25 microM and 8 microM, respectively. The fructose phosphorylation rate equation is given as a function of the concentration of the two enzymes and the two substrates.

Mannitol-specific carrier protein from the Escherichia coli phosphoenolpyruvate-dependent phosphotransferase system can be extracted as a dimer from the membrane

The association state of the mannitol-specific enzyme II (EIIMtl) has been studied both in the purified form and embedded in the cytoplasmic membrane. Membrane fragments obtained from mannitol-grown Escherichia coli catalyze the phosphoenolpyruvate- (PEP) dependent phosphorylation of both glucose and mannitol; thus they contain both the glucose- and mannitol-specific enzymes II. The autoradiogram of an electrophoresed mixture of [32P]PEP, EI, HPr, and membrane fragments shows bands at 58 and 116 kilodaltons, in addition to the bands of P-EI and P-HPr. In an analogous experiment with purified EIIMtl, suspended in detergent micelles, only a 58 000-dalton band and the P-HPr and P-EI bands were found. Treatment of the phosphorylated membranes with mannitol results in an immediate substantial decrease in the radioactivity in the 58- and 116-kilodalton bands. A similar treatment of the phosphorylated membranes with glucose had no direct effect on the autoradiogram. We conclude therefore that the 58- and 116-kilodalton bands originate from enzyme IIMtl monomers and dimers, respectively. The interaction between the subunits of the dimer is not abolished by the addition of up to 5% sodium dodecyl sulfate. However, the nonionic detergent Lubrol PX, which is present during the purification of EIIMtl, is capable of transforming the enzyme IIMtl dimers into monomers.