Coarse‐grained simulations of proton‐dependent conformational changes in lactose permease

During lactose/H⁺ symport, the Escherichia coli lactose permease (LacY) undergoes a series of global conformational transitions between inward‐facing (open to cytoplasmic side) and outward‐facing (open to periplasmic side) states. However, the exact local interactions and molecular mechanisms dictating those large‐scale structural changes are not well understood. All‐atom molecular dynamics simulations have been performed to investigate the molecular interactions involved in conformational transitions of LacY, but the simulations can only explore early or partial global structural changes because of the computational limits (< 100 ns). In this work, we implement a hybrid force field that couples the united‐atom protein models with the coarse‐grained MARTINI water/lipid, to investigate the proton‐dependent dynamics and conformational changes of LacY. The effects of the protonation states on two key glutamate residues (Glu325 and Glu269) have been studied. Our results on the salt‐bridge dynamics agreed with all‐atom simulations at early short time period, validating our simulations. From our microsecond simulations, we were able to observe the complete transition from inward‐facing to outward‐facing conformations of LacY. Our results showed that all helices have participated during the global conformational transitions and helical movements of LacY. The inter‐helical distances measured in our simulations were consistent with the double electron‐electron resonance experiments at both cytoplasmic and periplasmic sides. Our simulations indicated that the deprotonation of Glu325 induced the opening of the periplasmics side and partial closure of the cytoplasmic side of LacY, while protonation of the Glu269 caused a stable cross‐domain salt‐bridge (Glu130‐Arg344) and completely closed the cytoplasmic side. Proteins 2016; 84:1067–1074. © 2016 Wiley Periodicals, Inc.     

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.     

Thiol cross-linking of transmembrane domains IV and V in the lactose permease of Escherichia coli

Glu126 (helix IV) and Arg144 (helix V) in the lactose permease of Escherichia coli are critical for substrate binding and transport, and the two residues are in close proximity and charge-paired. By using a functional permease construct with two tandem factor Xa protease sites in the cytoplasmic loop between helices IV and V, it is shown here that Cys residues in place of Glu126 and Arg144, as well as Ala122 and Val149, spontaneously form disulfide bonds in situ, indicating that this region of transmembrane domains IV and V is in the alpha-helical conformation. To determine if the local structure or environment is perturbed by the presence of an unpaired charge, either Glu126 or Arg144 or both were replaced with Ala, and cross-linking between the Cys pair Ala122-->Cys/Val149-->Cys was studied. Ala replacement for Arg144 causes a marked decrease in cross-linking, while Ala replacement for Glu126 alone or for both Glu126 and Arg144 has little effect. The data provide strong support for the argument that Glu126 and Arg144 are within close proximity and suggest that an unpaired carboxylate at position 126 causes a structural change at the interface between helices IV and V.     

Functional conservation in the putative substrate binding site of the sucrose permease from Escherichia coli

The sucrose (CscB) permease is the only member of the oligosaccharide:H(+) symporter family in the Major Facilitator Superfamily that transports sucrose but not lactose or other galactosides. In lactose permease (lac permease), the most studied member of the family, three residues have been shown to participate in galactoside binding: Cys148 hydrophobically interacts with the galactosyl ring, while Glu126 and Arg144 are charge paired and form H-bonds with specific galactosyl OH groups. In the present study, the role of the corresponding residues in sucrose permease, Asp126, Arg144, and Ser148, is investigated using a functional Cys-less mutant (see preceding paper). Replacement of Ser148 with Cys has no significant effect on transport activity or expression, but transport becomes highly sensitive to the sulfhydryl reagent N-ethylmaleimide (NEM) in a manner similar to that of lac permease. However, in contrast to lac permease, substrate affords no protection whatsoever against NEM inactivation of transport or alkylation with [(14)C]NEM. Neutral (Ala, Cys) mutations of Asp126 and Arg144 abolish sucrose transport, while membrane expression is not affected. Similarly, combination of two Ala mutations within the same molecule (Asp126-->Ala/Arg144-->Ala) yields normally expressed, but completely inactive permease. Conservative replacements result in highly active molecules: Asp126-->Glu permease catalyzes sucrose transport comparable to Cys-less permease, while mutant Arg144-->Lys exhibits decreased but significant activity. The observations demonstrate that charge pair Asp126-Arg144 plays an essential role in sucrose transport and suggest that the overall architecture of the substrate binding sites is conserved between sucrose and lac permeases.     

Engineering conformational flexibility in the lactose permease of Escherichia coli: use of glycine-scanning mutagenesis to rescue mutant Glu325-->Asp

Lactose/H(+) symport by lactose permease of Escherichia coli involves interactions between four irreplaceable charged residues in transmembrane helices that play essential roles in H(+) translocation and coupling [Glu269 (helix VIII) with His322 (helix X) and Arg302 (helix IX) with Glu325 (helix X)], as well as Glu126 (helix IV) and Arg144 (helix V) which are obligatory for substrate binding. The conservative mutation Glu325-->Asp causes a 10-fold reduction in the V(max) for active lactose transport and markedly decreased lactose-induced H(+) influx with no effect on exchange or counterflow, neither of which involves H(+) symport. Thus, shortening the side chain may weaken the interaction of the carboxyl group at position 325 with the guanidino group of Arg302. Therefore, Gly-scanning mutagenesis of helices IX and X and the intervening loop was employed systematically with mutant Glu325-->Asp in an effort to rescue function by introducing conformational flexibility between the two helices. Five Gly replacement mutants in the Glu325-->Asp background are identified that exhibit significantly higher transport activity. Furthermore, mutant Val316-->Gly/Glu325-->Asp catalyzes active transport, efflux, and lactose-induced H(+) influx with kinetic properties approaching those of wild-type permease. It is proposed that introduction of conformational flexibility at the interface between helices IX and X improves juxtapositioning between Arg302 and Asp325 during turnover, thereby allowing more effective deprotonation of the permease on the inner surface of the membrane [Sahin-Tóth, M., Karlin, A., and Kaback, H. R. (2000) Proc. Natl. Acad. Sci. U.S.A. 97, 10729-10732.     

Proximity between Glu126 and Arg144 in the lactose permease of Escherichia coli.

Evidence has been presented [Venkatesan, P., and Kaback, H. R. (1998) Proc. Natl. Acad. Sci. U.S.A. 95, 9802-9807] that Glu126 (helix IV) and Arg144 (helix V) which are critical for substrate binding in the lactose permease of Escherichia coli are charge paired and therefore in close proximity. To test this conclusion more directly, three different site-directed spectroscopic techniques were applied to permease mutants in which Glu126 and/or Arg144 were replaced with either His or Cys residues. (1) Glu126-->His/Arg144-->His permease containing a biotin acceptor domain was purified by monomeric avidin affinity chromatography, and Mn(II) binding was assessed by electron paramagnetic resonance spectroscopy. The mutant protein binds Mn(II) with a KD of about 40 microM at pH 7.5, while no binding is observed at pH 5.5. In addition, no binding is detected with Glu126-->His or Arg144-->His permease. (2) Permease with Glu126-->Cys/Arg144-->Cys and a biotin acceptor domain was purified, labeled with a thiol-specific nitroxide spin-label, and shown to exhibit spin-spin interactions in the frozen state after reconstitution into proteoliposomes. (3) Glu126-->Cys/Arg144-->Cys permease with a biotin acceptor domain was purified and labeled with a thiol-specific pyrene derivative, and fluorescence spectra were obtained after reconstitution into lipid bilayers. An excimer band is observed with the reconstituted E126C/R144C mutant, but not with either single-Cys mutant or when the single-Cys mutants are mixed prior to reconstitution. The results provide strong support for the conclusion that Glu126 (helix IV) and Arg144 (helix V) are in close physical proximity.     

Aromatic stacking in the sugar binding site of the lactose permease

Major determinants for substrate recognition by the lactose permease of Escherichia coli are at the interface between helices IV (Glu126, Ala122), V (Arg144, Cys148), and VIII (Glu269). We demonstrate here that Trp151, one turn of helix V removed from Cys148, also plays an important role in substrate binding probably by aromatic stacking with the galactopyranosyl ring. Mutants with Phe or Tyr in place of Trp151 catalyze active lactose transport with time courses nearly the same as wild type. In addition, apparent K(m) values for lactose transport in the Phe or Tyr mutants are only 6- or 3-fold higher than wild type, respectively, with a comparable V(max). Surprisingly, however, binding of high-affinity galactoside analogues is severely compromised in the mutants; the affinity of mutant Trp151-->Phe or Trp151-->Tyr is diminished by factors of at least 50 or 20, respectively. The results demonstrate that Trp151 is an important component of the binding site, probably orienting the galactopyranosyl ring so that important H-bond interactions with side chains in helices IV, V, and VIII can be realized. The results are discussed in the context of a current model for the binding site.     

Monitoring conformational rearrangements in the substrate-binding site of a membrane transport protein by mass spectrometry

Combined biochemical, biophysical, and crystallographic studies on the lactose permease of Escherichia coli suggest that Arg-144 (helix V) forms a salt bridge with Glu-126 (helix IV), which is broken during substrate binding, thereby permitting the guanidino group to form a bidentate H-bond with the C-4 and C-3 O atoms of the galactopyranosyl moiety and an H-bond with Glu-269 (helix VIII). To examine the relative interaction of Arg-144 with these two potential salt bridge partners (Glu-126 and Glu-269) in the absence of substrate, the covalent modification of the guanidino group was monitored with the Arg-specific reagent butane-2,3-dione using electrospray ionization mass spectrometry. In a functional background, the reactivity of Arg-144 with butane-2,3-dione is low ( approximately 25%) and is reduced by a factor of approximately 2 by preincubation with ligand. Interestingly, although replacement of Glu-126 with Ala results in a 3-fold increase in the reactivity of Arg-144, replacement of Glu-269 with Ala elicits virtually no effect. Taken together, these results suggest that in the absence of substrate the interaction between Arg-144 and Glu-126 is much stronger than the interaction with Glu-269, supporting the contention that sugar recognition leads to rearrangement of charge-paired residues essential for sugar binding.     

Sugar transport across lactose permease probed by steered molecular dynamics

Escherichia coli lactose permease (LacY) transports sugar across the inner membrane of the bacterium using the proton motive force to accumulate sugar in the cytosol. We have probed lactose conduction across LacY using steered molecular dynamics, permitting us to follow molecular and energetic details of lactose interaction with the lumen of LacY during its permeation. Lactose induces a widening of the narrowest parts of the channel during permeation, the widening being largest within the periplasmic half-channel. During permeation, the water-filled lumen of LacY only partially hydrates lactose, forcing it to interact with channel lining residues. Lactose forms a multitude of direct sugar-channel hydrogen bonds, predominantly with residues of the flexible N-domain, which is known to contribute a major part of LacY's affinity for lactose. In the periplasmic half-channel lactose predominantly interacts with hydrophobic channel lining residues, whereas in the cytoplasmic half-channel key protein-substrate interactions are mediated by ionic residues. A major energy barrier against transport is found within a tight segment of the periplasmic half-channel where sugar hydration is minimal and protein-sugar interaction maximal. Upon unbinding from the binding pocket, lactose undergoes a rotation to permeate either half-channel with its long axis aligned parallel to the channel axis. The results hint at the possibility of a transport mechanism, in which lactose permeates LacY through a narrow periplasmic half-channel and a wide cytoplasmic half-channel, the opening of which is controlled by changes in protonation states of key protein side groups.     

Control of H<Superscript>+</Superscript>/Lactose Coupling by Ionic Interactions in the Lactose Permease of<Emphasis Type="Italic">Escherichia coli</Emphasis>

A combinatorial approach was used to study putative interactions among six ionizable residues (Asp-240, Glu-269, Arg-302, Lys-319, His-322, and Glu-325) in the lactose permease. Neutral mutations were made involving five ion pairs that had not been previously studied. Double mutants, R302L/E325Q and D240N/H322Q, had moderate levels of downhill [¹⁴C]-lactose transport. Mutants in which only one of these six residues was left unchanged (pentuple mutants) were also made. A Pent269⁻ mutant (in which only Glu-269 remains) catalyzed a moderate level of downhill lactose transport. Pent240⁻ and Pent 322⁺ also showed low levels of downhill lactose transport. Additionally, a Pent240⁻ mutant exhibited proton transport upon addition of melibiose, but not lactose. This striking result demonstrates that neutralization of up to five residues of the lactose permease does not abolish proton transport. A mutant with neutral replacements at six ionic residues (hextuple mutant) had low levels of downhill lactose transport, but no uphill accumulation or proton transport. Since none of the mutants in this study catalyzes active accumulation of lactose, this is consistent with other reports that have shown that each residue is essential for proper coupling. Nevertheless, none of the six ionizable residues is individually required for substrate-induced proton cotransport. These results suggest that the H⁺ binding domain may be elsewhere in the permease or that cation binding may involve a flexible network of charged residues.This revised version was published online in August 2005 with a corrected cover date.     

Nitroxide scanning electron paramagnetic resonance of helices IV and V and the intervening loop in the lactose permease of Escherichia coli

Glu126 and Arg144 in helices IV and V, respectively, in the lactose permease of Escherichia coli, which play an indispensable role in substrate binding, are charge-paired and in close proximity [Venkatesan, P., Kaback, H. R. (1998) Proc. Natl. Acad. Sci. U.S.A. 95, 9802-9807; Zhao, M., Zen, K.-C., et al. (1999) Biochemistry 38, 7407-7412]. Since hydropathy plots indicate that these residues are at the membrane-water interface at the cytoplasmic surface of the membrane, site-directed nitroxide scanning electron paramagnetic resonance (EPR) has been carried out on this region of the permease. Thirty-one single-Cys permease mutants were spin-labeled and examined by conventional and power saturation EPR. The motional freedom of the side chains, as well as accessibility to O(2) or potassium chromium oxalate (CrOx), indicates that the loop between helices IV and V (loop IV/V) is considerably smaller than predicted by hydropathy plots, extending only from about Val132 to Phe138 and that Glu126 and Arg144 are probably within the membrane. Although ligand binding has no effect on the mobility of the labeled side chains, a marked increase in CrOx and O(2) accessibility is observed at position 137, as well as significant changes in accessibility to CrOx on one face of helix V. It is concluded that ligand binding induces a conformational change in the vicinity of the binding site, resulting in increased accessibility of position 137 in loop IV/V to solvent.     

Structural evidence for induced fit and a mechanism for sugar/H+ symport in LacY

Cation-coupled active transport is an essential cellular process found ubiquitously in all living organisms. Here, we present two novel ligand-free X-ray structures of the lactose permease (LacY) of Escherichia coli determined at acidic and neutral pH, and propose a model for the mechanism of coupling between lactose and H+ translocation. No sugar-binding site is observed in the absence of ligand, and deprotonation of the key residue Glu269 is associated with ligand binding. Thus, substrate induces formation of the sugar-binding site, as well as the initial step in H+ transduction.     

The role of protons in the mechanism of galactoside transport via the lactose permease of Escherichia coli

The kinetic mechanism of lactose transport across the cytoplasmic membrane has been investigated and the results related to standard models for the lactose-H+ symport reaction using computer simulation. It is shown that the biphasic kinetics reported for lactose uptake (Kaczorowski, G.J. and Kaback, H.R. (1979) Biochemistry 18, 3691-3697) are consistent with random binding of lactose and protons and rapid subsequent translocation of the ternary lactose-H+-permease complex. Such a model is also shown to explain the observed dependence of the kinetic parameters on the magnitude of the protonmotive force. Both sugar and protons are shown to cause product inhibition of lactose flux and the ability of standard models to account for the pattern of inhibition is discussed. Three apparent dissociation constants have been determined for the protonation reactions in the external medium: two (pKa 6.3 and 9.6) control the activity of the permease, whilst the third (pKa 8.3) controls the affinity of the permease for galactosides. A similar set of dissociation constants has been determined for the internal reactions. Again two (pKa 6 and 9.8) control activity and a third (pKa 8.8) controls the affinity for galactosides. The dissociation reactions characterised by pKa 8.3, 8.8, 9.6 and 9.8 are attributed to the dissociation of the substrate (symported) proton from the binary proton-permease complexes (pKa 8.3 and 8.8) and the ternary proton-galactoside-permease complexes (pKa 9.6 and 9.8). The third pair (pKa 6.3 and 6.0) must be interpreted as describing a separate protonation reaction which may have a regulatory or auxiliary role in transport.     

Functional role of the "ionic lock"--an interhelical hydrogen-bond network in family A heptahelical receptors

Activation of family A G-protein-coupled receptors involves a rearrangement of a conserved interhelical cytoplasmic hydrogen bond network between the E(D)RY motif on transmembrane helix 3 (H3) and residues on H6, which is commonly termed the cytoplasmic “ionic lock.” Glu134^3.49 of the E(D)RY motif also forms an intrahelical salt bridge with neighboring Arg135^3.50 in the dark-state crystal structure of rhodopsin. We examined the roles of Glu134^3.49 and Arg135^3.50 on H3 and Glu247^6.30 and Glu249^6.32 on H6 on the activation of rhodopsin using Fourier transform infrared spectroscopy of wild-type and mutant pigments reconstituted into lipid membranes. Activation of rhodopsin is pH-dependent with proton uptake during the transition from the inactive Meta I to the active Meta II state. Glu134^3.49 of the ERY motif is identified as the proton-accepting group, using the Fourier transform infrared protonation signature and the absence of a pH dependence of activation in the E134Q mutant. Neutralization of Arg135^3.50 similarly leads to pH-independent receptor activation, but with structural alterations in the Meta II state. Neutralization of Glu247^6.30 and Glu249^6.32 on H6, which are involved in interhelical interactions with H3 and H7, respectively, led to a shift toward Meta II in the E247Q and E249Q mutants while retaining the pH sensitivity of the equilibrium. Disruption of the interhelical interaction of Glu247^6.30 and Glu249^6.32 on H6 with H3 and H7 plays its role during receptor activation, but neutralization of the intrahelical salt bridge between Glu134^3.49 and Arg135^3.50 is considerably more critical for shifting the photoproduct equilibrium to the active conformation. These conclusions are discussed in the context of recent structural data of the β₂-adrenergic receptor.     

Elucidation of substrate binding interactions in a membrane transport protein by mass spectrometry

Integration of biochemical and biophysical data on the lactose permease of Escherichia coli has culminated in a molecular model that predicts substrate-protein proximities which include interaction of a hydroxyl group in the galactopyranosyl ring with Glu269. In order to test this hypothesis, we studied covalent modification of carboxyl groups with carbodiimides using electrospray ionization mass spectrometry (ESI-MS) and demonstrate that substrate protects the permease against carbodiimide reactivity. Further more, a significant proportion of the decrease in carbodiimide reactivity occurs specifically in a nanopeptide containing Glu269. In contrast, carbodiimide reactivity of mutant Glu269-->Asp that exhibits lower affinity is unaffected by substrate. By monitoring the ability of different substrate analogs to protect against carbodiimide modification of Glu269, it is suggested that the C-3 OH group of the galactopyranosyl ring may play an important role in specificity, possibly by H-bonding with Glu269. The approach demonstrates that mass spectrometry can provide a powerful means of analyzing ligand interactions with integral membrane proteins.     

Contribution of arginine-glutamate salt bridges to helix stability

Peptide side chain interactions were studied by molecular dynamics simulation using explicit solvent on a peptide with the sequence AAARAAAAEAAEAAAARA. Three different protonation states of the glutamic acid side chains were simulated for four 20 ns runs each, a total simulation time of 240 ns. Two different salt bridge geometries were observed and the preferred geometry was found to depend on Glu — Arg residue spacing. Stable charge clusters were also observed, particularly in the fully charged peptide. Salt bridges were selectively interrupted upon protonation, with concomitant changes in secondary structure. The fully charged peptide was highly helical between residues 9 and 13, although protonation increased helicity near the N-terminus. The contribution of salt bridges to helix stability therefore depends on both position and relative position of charged residues within a sequence.     

Site-directed mutagenesis of lysine 319 in the lactose permease of Escherichia coli.

Lys319, which is on the same face of putative helix X as His322 and Glu325 in the lactose permease of Escherichia coli, has been replaced with Leu by oligonucleotide-directed, site-specific mutagenesis. Although previous experiments suggested that the mutation does not alter permease activity, we report here that K319L permease is unable to catalyze active lactose accumulation or lactose efflux down a concentration gradient. The mutant does catalyze facilitated influx down a concentration gradient at a significant rate; however, the reaction occurs without concomitant H+ translocation. The mutant also catalyzes equilibrium exchange at about 50% of the wild-type rate, but it exhibits poor counterflow activity. Finally, flow dialysis and photoaffinity labeling experiments with p-nitrophenyl alpha-D-galactopyranoside indicate that K319L permease probably has a markedly decreased affinity for substrate. The alterations described are not due to diminished levels of the mutated protein in the membrane, since immunological studies reveal comparable amounts of permease in wild-type and K319L membranes. It is proposed that Lys319, like Arg302, His322, and Glu325, plays an important role in active lactose transport, as well as substrate recognition.     

Probing the Periplasmic-Open State of Lactose Permease in Response to Sugar Binding and Proton Translocation

Based on the crystal structure of lactose permease (LacY) open to the cytoplasm, a hybrid molecular simulation approach with self-guided Langevin dynamics is used to describe conformational changes that lead to a periplasmic-open state. This hybrid approach consists of implicit (IM) and explicit (EX) membrane simulations and requires self-guided Langevin dynamics to enhance protein motions during the IM simulations. The pore radius of the lumen increases by 3.5 Å on the periplasmic side and decreases by 2.5 Å on the cytoplasmic side (relative to the crystal structure), suggesting a lumen that is fully open to the periplasm to allow for extracellular sugar transport and closed to the cytoplasm. Based on our simulations, the mechanism that triggers this conformational change to the periplasmic-open state is the protonation of Glu269 and binding of the disaccharide. Then, helix packing is destabilized by breaking of several side chains involved in hydrogen bonding (Asn245, Ser41, Glu374, Lys42, and Gln242). For the periplasmic-open conformations obtained from our simulations, helix-helix distances agree well with experimental measurements using double electron-electron resonance, fluorescence resonance energy transfer, and varying sized cross-linkers. The periplasmic-open conformations are also in compliance with various substrate accessibility/reactivity measurements that indicate an opening of the protein lumen on the periplasmic side on sugar binding. The comparison with these measurements suggests a possible incomplete closure of the cytoplasmic half in our simulations. However, the closure is sufficient to prevent the disaccharide from transporting to the cytoplasm, which is in accordance with the well-established alternating access model. Ser53, Gln60, and Phe354 are determined to be important in sugar transport during the periplasmic-open stage of the sugar transport cycle and the sugar is found to undergo an orientational change in order to escape the protein lumen.     

Characterization of site-directed mutants in the lac permease of Escherichia coli. 2. Glutamate-325 replacements

lac permease with Ala in place of Glu325 was solubilized from the membrane, purified, and reconstituted into proteoliposomes. The reconstituted molecule is completely unable to catalyze lactose/H+ symport but catalyzes exchange and counterflow at least as well as wild-type permease. In addition, Ala325 permease catalyzes downhill lactose influx without concomitant H+ translocation and binds p-nitrophenyl alpha-D-galactopyranoside with a KD only slightly higher than that of wild-type permease. Studies with right-side-out membrane vesicles demonstrate that replacement of Glu325 with Gln, His, Val, Cys, or Trp results in behavior similar to that observed with Ala in place of Glu325. On the other hand, permease with Asp in place of Glu325 catalyzes lactose/H+ symport about 20% as well as wild-type permease. The results indicate that an acidic residue at position 325 is essential for lactose/H+ symport and that hydrogen bonding at this position is insufficient. Taken together with previous results and those presented in the following paper [Lee, J. A., Püttner, I. B., & Kaback, H. R. (1989) Biochemistry (third paper of three in this issue)], the findings are consistent with the idea that Arg302, His322, and Glu325 may be components of a H+ relay system that plays an important role in the coupled translocation of lactose and H+.     

Helix packing in the lactose permease of Escherichia coli determined by site-directed thiol cross-linking: helix I is close to helices V and XI

Coexpression of lacY gene fragments encoding the first two transmembrane domains and the remaining 10 transmembrane domains complement in the membrane and catalyze active lactose transport [Wrubel, W., Stochaj, U., et al. (1990) J. Bacteriol. 172, 5374-5381]. Accordingly, a plasmid encoding contiguous, nonoverlapping permease fragments with a discontinuity in the cytoplasmic loop between helices II and III (loop II/III) was constructed (N2C10 permease). When Phe27 (helix I) is replaced with Cys, cross-linking is observed with two native Cys residues, Cys148 (helix V) and Cys355 (helix XI). Cross-linking of a Cys residue at position 27 to Cys148 occurs with N,N'-o-phenylenedimaleimide (o-PDM; rigid 6 A), with N,N'-p-phenylenedimaleimide (p-PDM; rigid 10 A), or with 1,6-bis(maleimido)hexane (BMH; flexible 16 A). On the other hand, with the Phe27-->Cys/Cys355 pair, cross-linking is observed with p-PDM or BMH but not o-PDM. In neither case is cross-linking observed with iodine. It is suggested that a Cys residue at position 27 is within 6-10 A from Cys148 and about 10 A from Cys355. The results provide evidence for proximity between helix I and helices V or XI in the tertiary structure of the permease. In addition, the findings are consistent with other results [Venkatesan, P., Kaback, H. R. (1998) Proc. Natl. Acad. Sci. U.S.A. 95, 9802-9807] indicating that Glu126 (helix IV) and Arg144 (helix V) are within the membrane, rather than at the membrane-water interface on the cytoplasmic face.