Binding of spin-labeled galactosides to the lactose permease of Escherichia coli

A series of nitroxide spin-labeled alpha- or beta-galactopyranosides and a nitroxide spin-labeled beta-glucopyranoside have been synthesized and examined for binding to the lactose permease of Escherichia coli. Out of the twelve nitroxide spin-labeled galactopyranosides synthesized, 1-oxyl-2, 5, 5-trimethyl-2-[3-nitro-4-N-(hexyl-1-thio-beta-D-galactopyranosid-1 -yl )]aminophenyl pyrrolidine (NN) exhibits the highest affinity for the permease based on the following observations: (a) the analogue inhibits lactose transport with a K(I) about 7 microM; (b) NN blocks labeling of single-Cys148 permease with 2-(4'-maleimidylanilino) naphthalene-6-sulfonic acid (MIANS) with an apparent affinity of about 12 microM; (c) electron paramagnetic resonance demonstrates binding of the spin-labeled sugar by purified wild-type permease in a manner that is reversed by nonspin-labeled ligand. The equilibrium dissociation constant (K(D)) is about 23 microM and binding stoichiometry is approximately unity. In contrast, the nitroxide spin-labeled glucopyranoside does not inhibit active lactose transport or labeling of single-Cys148 permease with MIANS. It is concluded that NN binds specifically to lac permease with an affinity in the low micromolar range. Furthermore, affinity of the permease for the spin-labeled galactopyranosides is directly related to the length, hydrophobicity, and geometry of the linker between the galactoside and the nitroxide spin-label.     

Two-dimensional crystallization of Escherichia coli lactose permease

A chimeric protein consisting of lactose permease with cytochrome b562 in the middle cytoplasmic loop and six His residues at the C terminus (LacY/L6cytb562/417H6 or "red permease") was overexpressed in Escherichia coli and isolated by nickel affinity chromatography after solubilization with dodecyl-beta,d-maltopyranoside. Red permease was then reconstituted in the presence of phospholipids, yielding densely packed vesicles and well-ordered two-dimensional (2D) crystals as shown by electron microscopy of negatively stained specimens. Single-particle analysis of 16 383 protein particles in densely packed vesicles reveals a 5.4-nm-long trapeziform protein of 4.1 to 5.1 nm width, with a central stain-filled indentation. Depending on reconstitution conditions, trigonal and rectangular crystallographic packing arrangements of these elongated particles assembled into trimers are observed. The best ordered 2D crystals exhibit a rectangular unit cell, of dimensions a = 9.9 nm, b = 17.4 nm, that houses two trimeric complexes. Projection maps calculated to a resolution of 2 nm show that these crystals consist of two layers.     

Topography of lactose permease from Escherichia coli

The topography of lactose permease, in native membrane vesicles and after reconstitution of the purified protein into proteoliposomes, has been investigated by labeling the membrane-embedded portions of the protein using photoactivatable, hydrophobic reagents and by labeling the exposed portions of the protein with water-soluble, electrophilic reagents. Some sites of modification have been localized in fragments of the protein produced by chemical and enzymatic cleavage. These define a number of hydrophilic loops and membrane-spanning regions and give some substance to topographic models of the permease. The N-terminal third of the molecule was labeled by three photoactivatable reagents (3-(trifluoromethyl)-3-m-iodophenyldiazirine and the phospholipid analogues 2-(aceto-(4-benzoylphenylether]-1-palmitoylphosphatidylcholine) and 2-(4-azido-2-nitrophenylaminoacetyl)-1-palmitoylphosphatidylcholin e) as well as the water soluble, electrophilic reagents. The C-terminal part of the molecule is labeled by the diazirine and, to a lesser extent, by the phospholipid analogues. It apparently has more nucleophilic groups accessible to water-soluble reagents than the N-terminal domain, in which the density of apparently unreactive ionizable residues proved to be unexpectedly high. The apparent lack of reactivity of some of these residues may be explained either by their being buried in the protein moiety within the membrane domain, or by their close association with other ionizable residues on the surface of the protein.     

Sugar recognition by the lactose permease of Escherichia coli

Biochemical, luminescence and mass spectroscopy approaches indicate that Trp-151 (helix V) plays an important role in hydrophobic stacking with the galactopyranosyl ring of substrate and that Glu-269 (helix VIII) is essential for substrate affinity and specificity. The x-ray structure of the lactose permease (LacY) with bound substrate is consistent with these conclusions and suggests that a possible H-bond between Glu-269 and Trp-151 may play a critical role in the architecture of the binding site. We have now probed this relationship by exploiting the intrinsic luminescence of a single Trp-151 LacY with various replacements for Glu-269. Mutations at position 269 dramatically alter the environment of Trp-151 in a manner that correlates with binding affinity of LacY substrates. Furthermore, chemical modification of Trp-151 with N-bromosuccinimide indicates that Glu-269 forms an H-bond with the indole N. It is concluded that 1) an H-bond between the indole N and Glu-269 optimizes the formation of the substrate binding site in the inward facing conformation of LacY, and 2) the disposition of the residues implicated in sugar binding in different conformers suggests that sugar binding by LacY involves induced fit.     

Binding of monoclonal antibody 4B1 to homologs of the lactose permease of Escherichia coli.

The conformationally sensitive epitope for monoclonal antibody (mAb) 4B1, which uncouples lactose from H+ translocation in the lactose permease of Escherichia coli, is localized in the periplasmic loop between helices VII and VIII (loop VII/VIII) on one face of a short helical segment (Sun J, et al., 1996, Biochemistry 35;990-998). Comparison of sequences in the region corresponding to loop VII/VIII in members of Cluster 5 of the Major Facilitator Superfamily (MFS), which includes five homologous oligosaccharide/H+ symporters, reveals interesting variations. 4B1 binds to the Citrobacter freundii lactose permease or E. coli raffinose permease with resultant inhibition of transport activity. Because E. coli raffinose permease contains a Pro residue at position 254 rather than Gly, it is unlikely that the mAb recognizes the peptide backbone at this position. Consistently, E. coli lactose permease with Pro in place of Gly254 also binds 4B1. In contrast, 4B1 binding is not observed with either Klebsiella pneumoniae lactose permease or E. coli sucrose permease. When the epitope is transferred from E. coli lactose permease (residues 245-259) to the sucrose permease, the modified protein binds 4B1, but the mAb has no significant effect on sucrose transport. The studies provide further evidence that the 4B1 epitope is restricted to loop VII/VIII, and that 4B1 binding induces a highly specific conformational change that uncouples substrate and H+ translocation.     

Limited proteolysis of lactose permease from Escherichia coli

Escherichia coli lactose permease (also referred to as lactose carrier) is an integral protein of the cytoplasmic membrane. Using lactose permease either radiolabeled biosynthetically in plasmid-bearing E. coli minicells or radioalkylated post-synthetically by chemical modification, we have determined sites on the membrane-bound protein accessible to proteolytic attack and we have characterized several high-molecular-mass products. The most prominent polypeptide obtained from lactose permease radiolabeled biosynthetically is observed after digestion with different proteases. The fragment produced by thermolysin was shown to contain the intact N-terminus and to extend into the region around amino acid residue 140 which, according to secondary structure models, is presumed to be less tightly folded than the rest of the molecule. Evidence is presented that the corresponding fragments obtained after digestion with several other proteases also originate from the N-terminal part of the protein. This N-terminal segment of the lactose carrier is resistant to proteolytic digestion even in the presence of non-ionic detergents and it may represent a tightly folded domain. Additional proteolytic cleavage sites located C-terminal of the Cys148 residue can be inferred.     

Membrane assembly of lactose permease of Escherichia coli.

Lactose permease, the lacY gene product in Escherichia coli, is an integral membrane protein. Its induction was examined in secAts and secYts mutants by measuring o-nitrophenyl-beta-galactoside uptake activity. In contrast to the synthesis of the maltose binding protein, the malE gene product, which is dependent on the secA and secY gene products, lactose permease seemed to be produced and integrated functionally into membrane independently of SecA or SecY. Gene fusion of the lamB signal sequence to the N-terminal part of the lactose permease gene resulted in production of active fused permease in the E. coli membrane. The signal sequence did not seem to be processed, judging from its mobility on SDS polyacrylamide gel electrophoresis. E. coli cell growth was super-sensitive to induction of production of the fused permease with the signal sequence in contrast to induction of the normal lactose permease. These results are consistent with the above observation that production and integration of LacY protein into membrane is relatively independent of the SecY protein that may have a certain specificity for the signal sequence or, more generally, membrane translocation intermediates.     

Counter-transport mediated by the lactose permease of Escherichia coli.

When the two main energy yielding pathways, respiration and the membrane ATPase of Escherichia coli are poisoned, the lactose permease is unable to accomplish accumulative transport of thiogalactosides, but the efflux of preloaded substrate can be coupled to a transiently uphill transport of exogenous substrate. This transient uphill transport, called overshoot has been reexamined with the possibility of an obligate H+ cotransport in mind. Overshoot can be diminished but not suppressed by a proton-conducting uncoupler, carbonyl cyanide m chlorophenylhydrazone, (CCCP) and by a liposoluble cation, triphenyl-methyl phosphonium (TPMP+). The effect of other factors, such as temperature, amount of permease and pH were also explored. The overshoot was found to decrease with increasing pH, until at pH 8 it became negligible. This is in sharp contrast with the relatively flat pH dependence of uphill and downhill transport in unpoisoned cells. CCCP and TPMP+ had no inhibitory effect on the overshoot at pH 6 and below.     

Binding of p-nitrophenyl alpha-D-galactopyranoside to lac permease of Escherichia coli

Binding of the substrate analogue p-nitrophenyl alpha-D-galactopyranoside (NPG) to lac permease of Escherichia coli in different membrane preparations was investigated. Binding was assayed with an improved version of the centrifugation technique introduced by Kennedy et al. [Kennedy, E.P., Rumley, M.V., Armstrong, J.B. (1974) J. Biol. Chem. 249, 33-37]. Two binding sites for NPG were found with dissociation constants of about 16 microM and 1.6 mM at pH 7.5 and room temperature. With purified lac permease reconstituted into proteoliposomes, it could be shown that one permease molecule binds two substrate molecules. Oxidation of lac permease with the lipophilic quinone plumbagin or alkylation with the sulfhydryl reagent N-ethylmaleimide caused a 12-fold increase in the first dissociation constant. The second dissociation constant seemed to be increased as well, but its value could not reliably be estimated. Ethoxyformylation of lac permease with diethyl pyrocarbonate totally abolished NPG binding. The implications of these results for the catalytic performance of the enzyme are discussed.     

Manipulating conformational equilibria in the lactose permease of Escherichia coli.

A mechanism proposed for lactose/H(+) symport by the lactose permease of Escherichia coli indicates that lactose permease is protonated prior to ligand binding. Moreover, in the ground state, the symported H(+) is shared between His322 (helix X) and Glu269 (helix VIII), while Glu325 (helix X) is charge-paired with Arg302 (helix IX). Substrate binding at the outer surface between helices IV (Glu126) and V (Arg144, Cys148) induces a conformational change that leads to transfer of the H(+) to Glu325 and reorientation of the binding site to the inner surface. After release of substrate, Glu325 is deprotonated on the inside due to re-juxtapositioning with Arg302. The conservative mutation Glu269-->Asp causes a 50-100-fold decrease in substrate binding affinity and markedly reduced active lactose transport, as well as decreased rates of equilibrium exchange and efflux. Gly-scanning mutagenesis of helix VIII was employed systematically with mutant Glu269-->Asp in an attempt to rescue function, and two mutants with increased activity are identified and characterized. Mutant Thr266-->Gly/Met267-->Gly/Glu269-->Asp binds ligand with increased affinity and catalyzes active lactose transport with a marked increase in rate; however, little improvement in efflux or equilibrium exchange is observed. In contrast, mutant Gly262-->Ala/Glu269-->Asp exhibits no improvement in ligand binding but a small increase in the rate of active transport; however, an increase in the steady-state level of accumulation, as well as efflux and equilibrium exchange is observed. Remarkably, when the two sets of mutations are combined, all translocation reactions are rescued to levels approximating those of wild-type permease. The findings support the contention that Glu269 plays a pivotal role in the mechanism of lactose/H(+) symport. Moreover, the results suggest that the two classes of mutants rescue activity by altering the equilibrium between outwardly and inwardly facing conformations of the permease such that impaired protonation and/or H(+) transfer is enhanced from one side of the membrane or the other. When the two sets of mutants are combined, the equilibrium between outwardly and inwardly facing conformations and thus protonation and H(+) transfer are restored.     

Transport by the lactose permease of Escherichia coli as the basis of lactose killing.

Lactose killing is a peculiar phenomenon in which 80 to 98% of the Escherichia coli cells taken from a lactose-limited chemostat die when plated on standard lactose minimal media. This unique form of suicide is caused by the action of the lactose permease. Since uptake of either lactose or galactose by the lactose permease caused death, the action of rapid transport across the membrane must be the cause of the phenomenon. Alternative causes of lactose killing, such as accumulation of toxic metabolic intermediates or action of the beta-galactosidase, have been eliminated. It is proposed that rapid uptake of sugars by the lactose permease disrupts membrane function, perhaps causing collapse of the membrane potential.     

Modeling FRET to investigate the selectivity of lactose permease of Escherichia coli for lipids

Förster resonance energy transfer (FRET) is a photophysical process by which a donor (D) molecule in an electronic excited state transfers its excitation energy to a second species, the acceptor (A). Since FRET efficiency depends on D-A separation, the measurement of donor fluorescence in presence and absence of the acceptor allows determination of this distance, and therefore FRET has been extensively used as a “spectroscopic ruler”. In membranes, interpretation of FRET is more complex, since one D may be surrounded by many A molecules. Such is the case encountered with membrane proteins and lipids in the bilayer. This paper reviews the application of a model built to analyze FRET data between a single tryptophan mutant of the transmembrane protein lactose permease (W151/C154G of LacY), the sugar/H⁺ symporter from Escherichia coli, and different pyrene-labeled phospholipids. Several variables of the system with biological implication have been investigated: The selectivity of LacY for different species of phospholipids, the enhancement of the sensitivity of the FRET modeling, and the mutation of a particular aminoacid (D68C) of the protein. The results obtained support: (i) Preference of LacY for phosphatidylethanolamine (PE) over phosphatidylglycerol (PG); (ii) affinity of LacY for fluid (L_α) phases; and (iii) importance of the aspartic acid in position 68 in the sequence of LacY regarding the interaction with the phospholipid environment. Besides, by exploring the enhancement of the sensitivity by using pure lipid matrices with higher mole fractions of labelled-phospholipid, the dependence on acyl chain composition is unveiled.     

Binding of enzyme IIAGlc, a component of the phosphoenolpyruvate:sugar phosphotransferase system, to the Escherichia coli lactose permease

Enzyme IIA(Glc), encoded by the crr gene of the phosphoenolpyruvate:sugar phosphotransferase system, plays an important role in regulating intermediary metabolism in Escherichia coli ("catabolite repression"). One function involves inhibition of inducible transport systems ("inducer exclusion"), and with lactose permease, a galactoside is required for unphosphorylated IIA(Glc) binding to cytoplasmic loops IV/V and VI/VII [Sondej, M., Sun, J. et al. (1999) Proc. Natl. Acad. Sci. U.S.A. 96, 3525-3530]. With inside-out membrane vesicles containing the permease, [(125)I]IIA(Glc) binding promoted by melibiose exhibits an affinity (K(D)(IIA)) of approximately 1 microM and a stoichiometry of one mole of IIA(Glc) per six moles of lactose permease. Both the quantity of [(125)I]IIA(Glc) bound and the sugar concentration required for half-maximal IIA(Glc) binding (K(0.5)(IIA)(sug)) was measured for eight permease substrates. Differences in maximal IIA(Glc) binding are observed, and the K(0.5)(IIA)(sug) does not correlate with the affinity of LacY for sugar. Furthermore, K(0.5)(IIA)(sug) does not correlate with sugar affinities for various permease mutants. IIA(Glc) does not bind to a mutant (Cys154 --> Gly), which is locked in an outwardly facing conformation, binds with increased stoichiometry to mutant Lys131 --> Cys, and binds only weakly to two other mutants which appear to be predominantly in either an outwardly or an inwardly facing conformation. When the latter two mutations are combined, sugar-dependent IIA(Glc) binding returns to near wild-type levels. The findings suggest that binding of various substrates to lactose permease results in a collection of unique conformations, each of which presents a specific surface toward the inner face of the membrane that can interact to varying degrees with IIA(Glc).     

Thiol cross-linking of cytoplasmic loops in the lactose permease of Escherichia coli

The N- and C-terminal halves of lactose permease, each with a single-Cys residue in a cytoplasmic loop, were coexpressed, and cross-linking was studied in the absence or presence of ligand. Out of the 68 paired-Cys mutants in cytoplasmic loops IV/V and VIII/IX or X/XI, three pairs in loop IV/V and X/XI, (i) Arg135 --> Cys/Thr338 --> Cys, (ii) Arg134 --> Cys/Val343 --> Cys, and (iii) Arg134 --> Cys/Phe345 --> Cys, form a spontaneous disulfide bond, indicating that loops IV/V and X/XI are in close proximity. In addition, specific paired-Cys residues in loop IV/V (132-138) and loop VIII/IX (282-290) or loop X/XI (335-345) cross-link with iodine and/or the homobifunctional cross-linking agents N, N'-o-phenylenedimaleimide, N,N'-p-phenylenedimaleimide, and 1, 6-bis(maleimido)hexane. The results demonstrate that loop IV/V is close to both loop VIII/IX and loop X/XI. On the other hand, similar though less extensive cross-linking studies indicate that neither the N terminus nor loop II/III appear to be close to loops VIII/IX or X/XI. The findings suggest that the longer cytoplasmic loops are highly flexible and interact in a largely random fashion. However, although a Cys residue at position 134 in loop IV/V, for example, is able to cross-link with a Cys residue at each position in loop VIII/IX or loop X/XI, Cys residues at other positions in loop IV/V exhibit markedly different cross-linking patterns. Therefore, although the domains appear to be very flexible, the interactions are not completely random, suggesting that there are probably at least some structural constraints that limit the degree of flexibility. In addition, evidence is presented suggesting that ligand binding induces conformational alterations between loop IV/V and loop VIII/IX or X/XI.     

Energetics of ligand-induced conformational flexibility in the lactose permease of Escherichia coli

Isothermal titration calorimetry has been applied to characterize the thermodynamics of ligand binding to wild-type lactose permease (LacY) and a mutant (C154G) that strongly favors an inward facing conformation. The affinity of wild-type or mutant LacY for ligand and the change in free energy (DeltaG) upon binding are similar. However, with the wild type, the change in free energy upon binding is due primarily to an increase in the entropic free energy component (TDeltaS), whereas in marked contrast, an increase in enthalpy (DeltaH) is responsible for DeltaG in the mutant. Thus, wild-type LacY behaves as if there are multiple ligand-bound conformational states, whereas the mutant is severely restricted. The findings also indicate that the structure of the mutant represents a conformational intermediate in the overall transport cycle.     

Interhelical packing modulates conformational flexibility in the lactose permease of Escherichia coli

A key to obtaining an X-ray structure of the lactose permease of Escherichia coli (LacY) (Abramson, J., Smirnova, I., Kasho, V., Verner, G., Kaback, H. R., and Iwata, S. (2003) Science 301, 549-716) was the use of a mutant in which Cys154 (helix V) is replaced with Gly. LacY containing this mutation strongly favors an inward-facing conformation, which binds ligand with high affinity, but catalyzes little transport and exhibits few if any of the ligand-dependent conformational changes observed with wild-type LacY. The X-ray structure demonstrates that helix V crosses helix I in the approximate middle of the membrane in such a manner that Cys154 lies close to Gly24 (helix I). Therefore, it seems likely that replacing Cys154 with Gly may lead to tighter packing between helices I and V, thereby resulting in the phenotype observed. Consistently, replacement of Gly24 with Cys in the C154G mutant rescues significant transport activity, and the mutant exhibits properties similar to wild-type LacY with respect to substrate binding and thermostability. However, the only other replacements that rescue transport to any extent whatsoever are Val and Asp, both of which are much less effective than Cys. The results suggest that, although helix packing probably plays an important role with respect to the properties of the C154G mutant, the ability of Cys at position 24 to rescue transport activity of C154G is more complicated than simple replacement of bulk between positions 24 and 154. Rather, activity is dependent on more subtle interactions between the helices, and mutations that disrupt interactions between helix IV and loop 6-7 or between helices II and IV also rescue transport in the C154G mutant.     

Atomic force microscopy study of Escherichia coli lactose permease proteolipid sheets

Proteolipid sheets (PLSs) obtained using the vesicle fusion technique on a convenient surface are the base to obtain transmembrane protein biosensors. In this preliminary work, we have screened several physicochemical conditions to optimize the visualization of proteolipid sheets formed between different phospholipid matrices and the membrane protein lactose permease (LacP) by atomic force microscopy (AFM). When LacP was reconstituted in 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) liposomes, the proteolipid sheets were densely packed with an upper layer that protruded from a background layer. Several lipid protein molar ratios (LPR) were screened. High resolution analysis of the upper layer revealed a quasi-crystalline arrangement formed by small entities that could be attributed to the protein. The approach described here may be suitable for the rational design of biosensors based in other transmembrane proteins.     

Effect of the lipid phase transition on the lactose permease from Escherichia coli

The temperature dependence of lactose active transport, efflux down a concentration gradient, and equilibrium exchange were analyzed in right-side-out membrane vesicles from Escherichia coli containing wild-type lactose permease and mutant Glu325 --> Ala. With respect to uphill transport and efflux down a concentration gradient, both of which involve H(+) symport, Arrhenius plots with wild-type permease exhibit a discontinuity at 18-19 degrees C with a 7-8-fold decrease in activation energy above the phase transition. For equilibrium exchange, which does not involve H(+) symport, the change in activation energy is much less pronounced (2-3-fold) than that observed for active transport or efflux. Strikingly, mutant Glu325 --> Ala, which catalyzes equilibrium exchange as well as wild-type permease but is defective in all translocation reactions that involve net H(+) translocation, exhibits no change whatsoever in activation energy. The findings are consistent with the conclusion that the primary effect of the lipid phase transition is to alter coupling between substrate and H(+) translocation rather than the conformational change(s) responsible for translocation across the membrane.