Cysteine cross-linking defines part of the dimer and B/C domain interface of the Escherichia coli mannitol permease.

Part of the dimer and B/C domain interface of the Escherichia coli mannitol permease (EII(mtl)) has been identified by the generation of disulfide bridges in a single-cysteine EII(mtl), with only the activity linked Cys(384) in the B domain, and in a double-cysteine EII(mtl) with cysteines at positions 384 and 124 in the first cytoplasmic loop of the C domain. The disulfide bridges were formed in the enzyme in inside-out membrane vesicles and in the purified enzyme by oxidation with Cu(II)-(1,10-phenanthroline)(3), and they were visualized by SDS-polyacrylamide gel electrophoresis. Discrimination between possible disulfide bridges in the dimeric double-cysteine EII(mtl) was done by partial digestion of the protein and the formation of heterodimers, in which the cysteines were located either on different subunits or on one subunit. The disulfide bridges that were identified are an intersubunit Cys(384)-Cys(384), an intersubunit Cys(124)-Cys(124), an intersubunit Cys(384)-Cys(124), and an intrasubunit Cys(384)-Cys(124). The disulfide bridges between the B and C domain were observed with purified enzyme and confirmed by matrix-assisted laser desorption ionization-time of flight mass spectrometry. Mannitol did not influence the formation of the disulfide between Cys(384) and Cys(124). The close proximity of the two cysteines 124 was further confirmed with a separate C domain by oxidation with Cu(II)-(1,10-phenanthroline)(3) or by reactions with dimaleimides of different length. The data in combination with other work show that the first cytoplasmic loop around residue 124 is located at the dimer interface and involved in the interaction between the B and C domain.

Multiple phosphorylation events regulate the activity of the mannitol transcriptional regulator MtlR of the Bacillus stearothermophilus phosphoenolpyruvate-dependent mannitol phosphotransferase system.

D-mannitol is taken up by Bacillus stearothermophilus and phosphorylated via a phosphoenolpyruvate-dependent phosphotransferase system (PTS). Transcription of the genes involved in mannitol uptake in this bacterium is regulated by the transcriptional regulator MtlR, a DNA-binding protein whose affinity for DNA is controlled by phosphorylation by the PTS proteins HPr and IICB(mtl). The mutational and biochemical studies presented in this report reveal that two domains of MtlR, PTS regulation domain (PRD)-I and PRD-II, are phosphorylated by HPr, whereas a third IIA-like domain is phosphorylated by IICB(mtl). An involvement of PRD-I and the IIA-like domain in a decrease in affinity of MtlR for DNA and of PRD-II in an increase in affinity is demonstrated by DNA footprint experiments using MtlR mutants. Since both PRD-I and PRD-II are phosphorylated by HPr, PRD-I needs to be dephosphorylated by IICB(mtl) and mannitol to obtain maximal affinity for DNA. This implies that a phosphoryl group can be transferred from HPr to IICB(mtl) via MtlR. Indeed, this transfer could be demonstrated by the phosphoenolpyruvate-dependent formation of [(3)H]mannitol phosphate in the absence of IIA(mtl). Phosphoryl transfer experiments using MtlR mutants revealed that PRD-I and PRD-II are dephosphorylated via the IIA-like domain. Complementation experiments using two mutants with no or low phosphoryl transfer activity showed that phosphoryl transfer between MtlR molecules is possible, indicating that MtlR-MtlR interactions take place. Phosphorylation of the same site by HPr and dephosphorylation by IICB(mtl) have not been described before; they could also play a role in other PRD-containing proteins.

The Bacillus stearothermophilus mannitol regulator, MtlR, of the phosphotransferase system. A DNA-binding protein, regulated by HPr and iicbmtl-dependent phosphorylation.

D-Mannitol is taken up by Bacillus stearothermophilus and phosphorylated via a phosphoenolpyruvate-dependent phosphotransferase system (PTS). The genes involved in the mannitol uptake were recently cloned and sequenced. One of the genes codes for a putative transcriptional regulator, MtlR. The presence of a DNA binding helix-turn-helix motif and two antiterminator-like PTS regulation domains, suggest that MtlR is a DNA-binding protein, the activity of which can be regulated by phosphorylation by components of the PTS. To demonstrate DNA binding of MtlR to a region upstream of the mannitol promoter, by DNA footprinting, MtlR was overproduced and purified. EI, HPr, IIAmtl, and IICBmtl of B. stearothermophilus were purified and used to demonstrate that MtlR can be phosphorylated and regulated by HPr and IICBmtl, in vitro. Phosphorylation of MtlR by HPr increases the affinity of MtlR for its binding site, whereas phosphorylation by IICBmtl results in a reduction of this affinity. The differential effect of phosphorylation, by two different proteins, on the DNA binding properties of a bacterial transcriptional regulator has not, to our knowledge, been described before. Regulation of MtlR by two components of the PTS is an example of an elegant control system sensing both the presence of mannitol and the need to utilize this substrate.

Cloning, expression, and isolation of the mannitol transport protein from the thermophilic bacterium Bacillus stearothermophilus.

A mannitol phosphotransferase system (PTS) was identified in Bacillus stearothermophilus by in vitro complementation with Escherichia coli EI, HPr, and IIA(Mtl). Degenerate primers based on regions of high amino acid similarity in the E. coli and Staphylococcus carnosus EII(Mt1) were used to develop a digoxigenin-labeled probe by PCR. Using this probe, we isolated three overlapping DNA fragments totaling 7.2 kb which contain the genes mtlA, mtlR, mtlF, and mtlD, encoding the mannitol IICB,a regulator, IIA, and a mannitol-1-phosphate dehydrogenase, respectively. The mtl4 gene consists of 1,413 bp coding for a 471-amino-acid protein with a calculated mass of 50.1 kDa. The amino acid sequence shows high similarity with the sequence of IICB(Mtl) of S. carnosus and the IICB part of the IICBA(Mtl)s of E. coli and B. subtilis. The enzyme could be functionally expressed in E. coli by placing it behind the strong tac promoter. The rate of thermal inactivation at 60 degrees C of B. stearothermophilus HCB(Mt1) expressed in E. coli was two times lower than that of E. coli IICB(Mtl). IICB(Mtl) in B. stearothermophilus is maximally active at 85 degrees C and thus very thermostable. The enzyme was purified on Ni-nitrilotriacetic acid resin to greater than 95% purity after six histidines were fused to the C-terminal part of the transporter.

Relation between the oligomerization state and the transport and phosphorylation function of the Escherichia coli mannitol transport protein: interaction between mannitol-specific enzyme II monomers studied by complementation of inactive site-directed mutants.

Previous experiments with the mannitol-specific enzyme II of Escherichia coli, EIImtl, have demonstrated that (1) the enzyme is a dimer, (2) the dimer is necessary for maximum activity, and (3) phosphoryl groups could be transferred between EIImtl subunits [van Weeghel et al. (1991) Biochemistry 30, 1768-1773; Weng et al. (1992) J. Biol. Chem. 267, 19529-19535; Weng & Jacobson (1993) Biochemistry 32, 11211-11216; Stolz et al. (1993) J. Biol. Chem. 268, 27094-27099]. The experiments in this article address the mechanistic role of the dimer. They indicate that the A, B, and C domains of EIImtl preferentially interact within the same subunit. Site-directed mutants in each of the three domains of EIImtl were used to study phosphoryl group transfer by the EIImtl dimer in vitro and mannitol transport in vivo. The C domain mutant, EIImtl-G196D, which was unable to bind mannitol, and the separated C domain, IICmtl, which was unable to phosphorylate mannitol, formed a heterodimer which was capable of mannitol phosphorylation in vitro and mannitol transport in vivo. The rates of phosphorylation were approximately 10-fold lower in heterodimers containing two inactive subunits relative to the rates in heterodimers containing one inactive and one wild type subunit; phosphoryl group transfer through one subunit is kinetically preferred to intersubunit transfer. Heterodimers formed in vivo between one wild type EIImtl subunit and the CB domain double mutant, EIImtl-G196D/C384S, transported mannitol as rapidly as wild type EIImtl alone; the presence of the inactive double mutant subunit did not reduce the transport rate. Thus, only one active A, B, and C domain in the dimer is sufficient for transport and phosphorylation activity, and if all three domains are situated on the same subunit, maximum rates are achieved.

Phosphorylation site mutants of the mannitol transport protein enzyme IImtl of Escherichia coli: studies on the interaction between the mannitol translocating C-domain and the phosphorylation site on the energy-coupling B-domain.

Mannitol binding and translocation catalyzed by the C domain of the Escherichia coli mannitol transport protein enzyme IImtl is influenced by domain B. This interaction was studied by monitoring the effects of mutating the B domain phosphorylation site, C384, on the kinetics of mannitol binding to the C domain. The dissociation constants for mannitol to the C384 mutants in inside-out membrane vesicles varied from 45 nM for the wild-type enzyme to 306 nM for the mutants. The rate constants pertinent to the binding equilibrium were also altered by the mutations. The association rate of mannitol to the cytoplasmic binding site in the mutants was accelerated for all mutants. The exchange rate of bound mannitol on the wild-type enzyme was shown to be pH dependent with a pKa of approximately 8 and increasing rates at higher pH. This rate was increased for all the mutants, but the pKas differed for the various mutants. The exchange rate for binding to the isolated IICmtl, however, was not pH dependent and exhibited a low rate. Exchange measured at 4 degrees C showed that, of the two steps, binding and occlusion, involved in binding to wild-type EIImtl in inside-out vesicles, only one could be detected for the C384E and C384L mutants. This suggests that the mutations increased the rate of the occlusion step so that it was no longer separable from the initial binding step or that the mutations eliminated the occlusion step altogether. The change in the mannitol binding kinetics of the C domain indicates that the B and C domains of EIImtl influence each other's conformation.(ABSTRACT TRUNCATED AT 250 WORDS)

Expression, purification, and kinetic characterization of the mannitol transport domain of the phosphoenolpyruvate-dependent mannitol phosphotransferase system of Escherichia coli. Kinetic evidence that the E. coli mannitol transport protein is a functional dimer.

The overexpression of the membrane-bound C domain of the mannitol transport protein EIIMtl of Escherichia coli has been achieved. This protein, IICMtl, consisting of the first 346 amino acids, was purified from membrane vesicles and still bound mannitol with a high affinity. Gel filtration experiments showed that purified IICMtl was a dimer, confirming that the interaction within the EIIMtl dimer occurs between the membrane-bound portions of the protein. IICMtl in combination with a chimeric protein consisting of the membrane-bound EIIGlc C domain and the cytoplasmic EIIMtl BA domain could restore both phosphoenolpyruvate-dependent phosphorylation and mannitol/mannitol-P exchange activity. The interaction in this complex was comparable to that of IICMtl with soluble IIBAMtl in as much as there appeared to be no specific interaction between IICMtl and the membrane-bound EIIGlc C domain; the Km of IICMtl for the chimer was so low that saturation could not be achieved. In contrast, a very high affinity with a Km of 2 nM was measured between purified IICMtl and purified EIIMtl. This interaction was manifested in a IICMtl-dependent stimulation of the EIIMtl catalyzed phosphoenolpyruvate-dependent mannitol phosphorylation reaction and the mannitol/mannitol-P exchange reaction. The high affinity of IICMtl for the wild type enzyme can be explained by the formation of heterodimers consisting of a IICMtl monomer and an EIIMtl monomer which interact at the level of the membrane-bound domains. The 2-fold increase in mannitol phosphorylation activity of the hetero- versus homodimer is an indication that the individual subunits in the homodimer are functionally coupled and work at only half their maximum rate. It is known that the EIIMtl dimer, but not the monomer, catalyzes the mannitol/mannitol-P exchange reaction. Since the heterodimer also catalyzes this reaction, it appears that only one functional B domain is required per dimer.

Steady state kinetics of mannitol phosphorylation catalyzed by enzyme IImtl of the Escherichia coli phosphoenolpyruvate-dependent phosphotransferase system.

The kinetics of mannitol phosphorylation catalyzed by enzyme IImtl of the bacterial P-enolpyruvate-dependent phosphotransferase system are described for three different physical conditions of the enzyme, (i) embedded in the membrane of inside-out (ISO) oriented vesicles, (ii) solubilized and assayed above the critical micellular concentration (cmc) of the detergent, and (iii) solubilized and assayed below the cmc of the detergent. The kinetic characteristics of enzyme IImtl, after solubilization of cytoplasmic membranes or after purification from these membranes are comparable. The mannitol-dependent kinetics at saturating concentration of P-HPr were biphasic both for the solubilized enzyme assayed above the cmc and for the enzyme in ISO vesicles. In contrast, the mannitol-dependent kinetics was monophasic for the solubilized enzyme assayed below the cmc. In the latter case, the maximal rate was about twice as high as observed with the two other conditions. The contribution of the high affinity phase to the maximal rate is lower for enzyme IImtl in ISO vesicles than for the solubilized enzyme. At limiting concentrations of P-HPr, the kinetics is not according to the expected "ping-pong" mechanism.

Mannitol-specific enzyme II of the phosphoenolpyruvate-dependent phosphotransferase system of Escherichia coli: physical size of enzyme IImtl and its domains IIBA and IIC in the active state.

The size of enzyme IImtl solubilized in the active state has been determined by size-exclusion chromatography under conditions that favor the association of the enzyme. The contribution of the detergent bound to the enzyme was determined by solubilizing the enzyme and running the TSK250 column in a number of detergents with decreasing micellar sizes. The size, expressed as the equivalent molecular mass of a globular protein, decreased from 315 kDa in decylPEG, to 275 kDa in octylPEG and octyl glucoside, and then to 245 kDa in cholate. Enzyme IImtl is not active in the latter three detergents when at concentrations above their cmc values but still binds mannitol with high affinity without significant loss of sites. This, together with the full reversibility of the inactivation, is taken as evidence that the enzyme does not unfold or dissociate in these detergents. The sizes of the separated domains IIBA and IIC of enzyme IImtl were 38 and 175 kDa, respectively. The cytoplasmic domain, IIBA, was monomeric at high concentration, whereas the membrane-bound domain, IIC, was associated at much lower concentration. Apparently, the sites that interact to keep enzyme IImtl in the associated state are exclusively located in the membrane-bound domain.

Mechanistic coupling of transport and phosphorylation activity by enzyme IImtl of the Escherichia coli phosphoenolpyruvate-dependent phosphotransferase system.

Mannitol bound to enzyme IImtl could be trapped specifically by rapid phosphorylation with P-HPr. The assay was used to demonstrate transport of mannitol across the cytoplasmic membrane with and without phosphorylation of mannitol. The latter was 2-3 orders of magnitude slower. The fraction of bound mannitol molecules that was actually phosphorylated, the efficiency of the trap, was less than 50%. The efficiency was not very different for enzyme IImtl embedded in the membrane of vesicles with an inside-out orientation or solubilized in detergent. Subsequently, it is argued that the fraction of the bound mannitol molecules that was not phosphorylated dissociated into the cytoplasmic space. A model for the catalytic mechanism of enzyme IImtl is proposed on the basis of interpretations of the present experiments. The main features of the model are the following: (i) mechanistically, the coupling between transport and phosphorylation is less than 50%; (ii) in the physiological steady state of mannitol transport and metabolism, the coupling is 100%; (iii) phosphorylated enzyme IImtl catalyzes facilitated diffusion at a high rate; (iv) the state of phosphorylation of the cytoplasmic domain modulates the activity of the translocator domain; (v) the enzyme catalyzes phosphorylation of free cytoplasmic mannitol at least as fast as it catalyzes transport plus phosphorylation of free periplasmic mannitol.

Interaction between the cytoplasmic and membrane-bound domains of enzyme IImtl of the Escherichia coli phosphoenolpyruvate-dependent phosphotransferase system.

Sulfhydryl reagents affected the binding properties of the translocator domain, NIII, of enzyme IImtl in two ways: (i) the affinity for mannitol was reduced, and (ii) the exchange rate of bound and free mannitol was increased. The effect on the affinity was very much reduced after solubilization of enzyme IImtl in the detergent decylPEG. The effects were caused exclusively by reaction of the sulfhydryl reagents with the cysteine residue at position 384 in the primary sequence. Interaction between two domains is involved, since Cys384 is located in the cytoplasmic domain, CII. When Cys384 was mutated to serine, the enzyme exhibited the same binding properties as the chemically modified enzyme. The data support our proposal that phosphorylation of enzyme IImtl drastically reduces the activation energy for the translocation step through interaction between domains CII and NIII [Lolkema J. S., ten Hoeve-Duurkens, R. H., Swaving Dijkstra, D., & Robillard, G. T. (1991) Biochemistry (preceding paper in this issue)]. Functional interaction between the translocator domain, NIII, and domain CI was investigated by phosphorylation of His554, located in domain CI, in the C384S mutant. No effect on the binding properties was observed. In addition, the binding properties were insensitive to the presence of the soluble phosphotransferase components enzyme I and HPr.

The membrane-bound domain of the phosphotransferase enzyme IImtl of Escherichia coli constitutes a mannitol translocating unit.

The orientation of the mannitol binding site on the Escherichia coli phosphotransferase enzyme IImtl in the unphosphorylated state has been investigated by measuring mannitol binding to cytoplasmic membrane vesicles with a right-side-out and inside-out orientation. Enzyme IImtl is shown to catalyze facilitated diffusion of mannitol at a low rate. At equilibrium, bound mannitol is situated at the periplasmic side of the membrane. The apparent binding constant is 40 nM for the intact membranes. Solubilization of the membranes in detergent decreases the affinity by about a factor of 2. Inside-out membrane vesicles, treated with trypsin to remove the C-terminal cytoplasmic domain of enzyme IImtl, showed identical activities. These experiments indicate that the translocation of mannitol is catalyzed by the membrane-bound N-terminal half of enzyme IImtl which is a structurally stable domain.

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.

The phosphoenolpyruvate-dependent fructose-specific phosphotransferase system in Rhodopseudomonas sphaeroides. Distribution of EIIFru over the membranes of phototrophically grown Rps. sphaeroides.

The distribution of the fructose carrier over the membranes of Rhodopseudomonas sphaeroides was studied in cells grown under light saturation and light limitation. Three types of membranes were isolated after disruption of the cells in a French press. All three types were present in the cells grown either under the high or low light intensity, but they were present in different quantities. The cytoplasmic membrane could be separated from the photosynthetic membranes by Sephacryl S-1000 chromatography. The cytoplasmic membrane has the highest specific density and fructose carrier content and does not contain the light-harvesting pigments. The photosynthetic membranes could be resolved into two types by sucrose density gradient centrifugation. Type A predominates when cells are grown under light saturation, whereas type B, the chromatophores, is synthesized abundantly under light limitation. The properties of type A are in between the properties of the cytoplasmic membrane and the chromatophores. It has a slightly lower specific density and contains four times less fructose carrier than the cytoplasmic membrane, but contains half of the light-harvesting bacteriochlorophyll of the chromatophore membrane. The fructose carrier content in the type B membranes, the chromatophores, is very low.

The phosphoenolpyruvate-dependent fructose-specific phosphotransferase system in Rhodopseudomonas sphaeroides. EIIFru possesses a Zn2+-binding site and a dithiol/disulfide redox centre.

Two interrelated sites have been detected on the fructose carrier in Rhodopseudomonas sphaeroides: an activity-linked dithiol and a Zn2+-binding site. Binding of Zn2+ brings EIIFru into a new conformation that to some extent mimics the conformation of phosphorylated EIIFru, an essential intermediate in the turnover of the enzyme. Binding of zinc to EIIFru or phosphorylating the enzyme protects it against trypsin inactivation relative to the dephosphorylated zinc-free enzyme. A dithiol is essential for activity. Interchanges between the redox states of the enzyme can be brought about by dithiothreitol and ferricyanide, but not, or very slowly, by molecular oxygen. The dithiol is protected, in the EIIFru-Zn2+ complex, against alkylation by MalNEt, reversible oxidation by Fe(CN)6(3-) and Cu2+, irreversible oxidation by Cu2+. The pK value of the activity linked thiol is 7.8. Protection experiments show that the dithiol is not located in any of the substrate-binding sites. The redox state of the enzyme does not influence the rate of inactivation of EIIFru by trypsin.

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 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.