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The role of helix VIII in the lactose permease of Escherichia coli: I. Cys-scanning mutagenesis
Abstract
Using a functional lactose permease mutant devoid of Cys residues (C-less permease), each amino acid residue in transmembrane domain VIII and flanking hydrophilic loops (from Gln 256 to Lys 289) was replaced individually with Cys. Of the 34 single-Cys mutants, 26 accumulate lactose to > 70% of the steady state observed with C-less permease, and an additional 7 mutants (Gly 262-->Cys, Gly 268-->Cys, Asn 272-->Cys, Pro 280-->Cys, Asn 284-->Cys, Gly 287-->Cys, and Gly 288-->Cys) exhibit lower but significant levels of accumulation (30-50% of C-less). As expected (Ujwal ML, Sahin-Tóth M, Persson B, Kaback HR, 1994, Mol Membr Biol 1:9-16), Cys replacement for Glu 269 abolishes lactose transport. Immunoblot analysis reveals that the mutants are inserted into the membrane at concentrations comparable to C-less permease, with the exceptions of mutants Pro 280-->Cys, Gly 287-->Cys, and Lys 289-->Cys, which are expressed at reduced levels. The transport activity of the mutants is inhibited by N-ethylmaleimide (NEM) in a highly specific manner. Most of the mutants are insensitive, but Cys replacements render the permease sensitive to inactivation by NEM at positions that cluster in manner indicating that they are on one face of an alpha-helix (Gly 262-->Cys, Val 264-->Cys, Thr 265-->Cys, Gly 268-->Cys. Asn 272-->Cys, Ala 273-->Cys, Met 276-->Cys, Phe 277-->Cys, and Ala 279-->Cys). The results indicate that transmembrane domain VIII is in alpha-helical conformation and demonstrate that, although only a single residue in this region of the permease is essential for activity (Glu 269), one face of the helix plays an important role in the transport mechanism. More direct evidence for the latter conclusion is provided in the companion paper (Frillingos S. Kaback HR, 1997, Protein Sci 6:438-443) by using site-directed sulfhydryl modification of the Cys-replacement mutants in situ.
... As shown in Figure 7 of the companion paper (Frillingos et al., 1997), the NEM-sensitive Cys-replacement mutants lie on a face of helix VI11 that lines part of an interface between helices V, VII, VIII, IX, X, and XI. ...
... encoding given single-Cys mutants were incubated with 2 mM NEM for the times indicated in the absence (0) or presence (+) of IO mM TDG as described (Frillingos et al., 1997). Reactions were terminated by addition of 20 mM DTT (final concentration), and the cells were washed extensively with I 0 0 mM KP, (pH 7.5)/10 mM MgS04 and resuspended at a final concentration of 0.7 mg proteinhl in the same buffer. ...
Cys-scanning mutagenesis of putative transmembrane helix VIII in the lactose permease of Escherichia coli (Frillingos S. Ujwal ML, Sun J, Kaback HR, 1997, Protein Sci 6:431-437) indicates that, although helix VIII contains only one irreplaceable residue (Glu 269), one face is important for active lactose transport. In this study, the rate of inactivation of each N-ethylmaleimide (NEM)-sensitive mutant is examined in the absence or presence of beta, D-galactopyranosyl 1-thio-beta,D-galactopyranoside (TDG). Remarkably, the analogue affords protection against inactivation with mutants Val 264-->Cys, Gly 268-->Cys, and Asn 272-->Cys, and alkylation of these single-Cys mutants in right-side-out membrane vesicles with [14C]NEM is attenuated by TDG. In contrast, alkylation of Thr 265-->Cys, which borders the three residues that are protected by TDG, is enhanced markedly by the analogue. Furthermore, NEM-labeling in the presence of the impermeant thiol reagent methanethiosulfonate ethylsulfonate demonstrates that ligand enhances the accessibility of position 265 to solvent. Finally, no significant alteration in NEM reactivity is observed for mutant Gly 262-->Cys, Glu 269-->Cys, Ala 273-->Cys, Met 276-->Cys, Phe 277-->Cys, or Ala 279-->Cys. The findings indicate that a portion of one face of helix VIII (Val 264, Gly 268, and Asn 272), which is in close proximity to Cys 148 (helix V), interacts with substrate, whereas another position bordering these residues (Thr 265) is altered by a ligand-induced conformational change.
... Cys scanning (Fig. 4, Fig. 5H), also previously used, is less sensitive than Ala scanning, but has the advantage that Cys can be crosslinked or readily covalently modified. [59,60] We propose to expand structure-activity relationship (SAR) studies that are currently limited to Ala scanning to include determining the mutation tolerance at each position. We designate this new approach as Structure/Activity/Tolerance Relationships (SATR). ...
High-throughput assay systems have had a large impact on understanding the mechanisms of basic cell functions. However, high-throughput assays that directly assess molecular functions are limited. Herein, we describe the “GigaAssay”, a modular high-throughput one-pot assay system for measuring molecular functions of thousands of genetic variants at once. In this system, each cell was infected with one virus from a library encoding thousands of Tat mutant proteins, with each viral particle encoding a random unique molecular identifier (UMI). We demonstrate proof of concept by measuring transcription of a GFP reporter in an engineered reporter cell line driven by binding of the HIV Tat transcription factor to the HIV long terminal repeat. Infected cells were flow-sorted into 3 bins based on their GFP fluorescence readout. The transcriptional activity of each Tat mutant was calculated from the ratio of signals from each bin. The use of UMIs in the GigaAssay produced a high average accuracy (95%) and positive predictive value (98%) determined by comparison to literature benchmark data, known C-terminal truncations, and blinded independent mutant tests. Including the substitution tolerance with structure/function analysis shows restricted substitution types spatially concentrated in the Cys-rich region. Tat has abundant intragenic epistasis (10%) when single and double mutants are compared.
... Possible role for residues 21-27 may be in allowing TonB to obtain the confirmation required for reinsertion into the ExbB/ExbD energy harvesting complex ? Kaback, 1993;Sahin-Toth et al., 1994a;Sahin-Toth et al., 1994b;Sahin-Toth et al., 1994c;Frillingos et al., 1994;Jung et al., 1995;Weitzman & Kaback, 1995;Frillingos & Kaback, 1996;Frillingos et al., 1997a;Frillingos et al., 1997b;Frillingos et al., 1997c;Kaback, 1997), and only two (Glu126 and Asp237) are important for the ability of lac permease to catalyze lactose influx down a concentration gradient (Frillingos et al., 1997a). The large amount of alanyl substitutions in the TMD of this research indicates that the absolute minimum requirement of residues for function in TonB may be very few. ...
... Experiments have shown that cysteine substitution in the residues from this loop has little effect on the transporter properties [51]. However, studies of the LacY transporter indicate that this does not necessarily mean that this segment is not important for transport, as it can be involved in conformational changes happening during the transport cycle [52]. To make sure that the truncation of this segment has little effect on our results, we have also built outward and inward models with the inclusion of the 4B-4C loop. ...
Excitatory amino acid transporters (EAATs) are membrane proteins that enable sodium-coupled uptake of glutamate and other amino acids into neurons. Crystal structures of the archaeal homolog GltPh have been recently determined both in the inward- and outward-facing conformations. Here we construct homology models for the mammalian glutamate transporter EAAT3 in both conformations and perform molecular dynamics simulations to investigate its similarities and differences from GltPh. In particular, we study the coordination of the different ligands, the gating mechanism and the location of the proton and potassium binding sites in EAAT3. We show that the protonation of the E374 residue is essential for binding of glutamate to EAAT3, otherwise glutamate becomes unstable in the binding site. The gating mechanism in the inward-facing state of EAAT3 is found to be different from that of GltPh, which is traced to the relocation of an arginine residue from the HP1 segment in GltPh to the TM8 segment in EAAT3. Finally, we perform free energy calculations to locate the potassium binding site in EAAT3, and find a high-affinity site that overlaps with the Na1 and Na3 sites in GltPh.
... 30. N272C transports lactose only 30% as well as the WT, 31 and site-directed alkylation demonstrates that mutants N272C, G268C, and V264C are protected against alkylation by the substrate, suggesting that all three positions might be in the vicinity of the sugar-binding site. 32 Moreover, sequence alignment data also show that Asn272 is conserved in bacterial galactoside/H + symporters. ...
Although an x-ray crystal structure of lactose permease (LacY) has been presented with bound galactopyranoside, neither the sugar nor the residues ligating the sugar can be identified with precision at ~3.5 Å. Therefore additional evidence is important for identifying side chains likely to be involved in binding. Based on a clue from site-directed alkylation suggesting that Asn272, Gly268 and Val264 on one face of helix VIII might participate in galactoside binding, molecular dynamics simulations were carried out initially. The simulations indicate that Asn272 (helix VIII) is sufficiently close to the galactopyranosyl ring of a docked lactose analogue to play an important role in binding, while the backbone at Gly268 may be involved, and Val264 does not interact with bound sugar. When the three side chains are subjected to site-directed mutagenesis, with the sole exception of mutant Asn272Gln, various other replacements for Asn272 either markedly decrease affinity for substrate (i.e., high KD) or abolish binding altogether. However, mutant Gly268Ala exhibits a moderate eight-fold decrease in affinity, and binding by mutant Val264Ala is affected only minimally. Thus, Asn272 and possibly Gly268 may comprise additional components of the galactoside-binding site in LacY.
... Residue E325 detects protonation states and transports H + with R302 and H322 on the periplasmic side, and P327 on the cytoplasmic side [33]. Substrate translocation is mediated by residues Y236, D240, F261, G262, and M299 of network 1 and residues A273 and M276 of network 2343536. Residues K319 in network 1 and G147 in network 2 are involved in substrate accumulation [28]. ...
The identification of functionally important residues is an important challenge for understanding the molecular mechanisms of proteins. Membrane protein transporters operate two-state allosteric conformational changes using functionally important cooperative residues that mediate long-range communication from the substrate binding site to the translocation pathway. In this study, we identified functionally important cooperative residues of membrane protein transporters by integrating sequence conservation and co-evolutionary information. A newly derived evolutionary feature, the co-evolutionary coupling number, was introduced to measure the connectivity of co-evolving residue pairs and was integrated with the sequence conservation score. We tested this method on three Major Facilitator Superfamily (MFS) transporters, LacY, GlpT, and EmrD. MFS transporters are an important family of membrane protein transporters, which utilize diverse substrates, catalyze different modes of transport using unique combinations of functional residues, and have enough characterized functional residues to validate the performance of our method. We found that the conserved cores of evolutionarily coupled residues are involved in specific substrate recognition and translocation of MFS transporters. Furthermore, a subset of the residues forms an interaction network connecting functional sites in the protein structure. We also confirmed that our method is effective on other membrane protein transporters. Our results provide insight into the location of functional residues important for the molecular mechanisms of membrane protein transporters.
... Studying the lactose permease of Escherichia coli, a polytopic membrane transport protein that catalyzes beta-galactoside/H þ symport, Frillingos et al. [40,41] used Cys-scanning mutagenesis in order to determine which residues play an obligatory role in the mechanism and to create a library of mutants with a single-Cys residue at each position of the molecule for structure/function studies. In general, these types of studies will define amino acid side chains that play an irreplaceable role in the transport mechanism and positions where the reactivity of the Cys replacement is altered upon ligand binding. ...
Solute carrier (SLC) proteins have critical physiological roles in nutrient transport and may be utilized as a mechanism to increase drug absorption. However, we have little understanding of these proteins at the molecular level due to the absence of high-resolution crystal structures. Numerous efforts have been made in characterizing the peptide transporter (PepT1) and the apical sodium dependent bile acid transporter (ASBT) that are important for both their native transporter function as well as targets to increase absorption and act as therapeutic targets. In vitro and computational approaches have been applied to gain some insight into these transporters with some success. This represents an opportunity for optimizing molecules as substrates for the solute transporters and providing a further screening system for drug discovery. Clearly the future growth in knowledge of SLC function will be led by integrated in vitro and in silico approaches.
... However, problems in interpreting signals generated from multiple reaction sites restrict substrate-dependent studies on Glu269 reactivity with radioactive or ¯uorescent carboxylate modifying reagents. Furthermore, replacement with Cys in a background devoid of native Cys residues renders LacY completely inactive and unable to bind ligand (Frillingos et al., 1997b), thereby precluding studies with thiol-speci®c reagents on single-Cys269 LacY. To overcome this obstacle, the covalent modi®cation of full-length puri®ed LacY by carboxyl-speci®c carbodiimides is monitored 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.
... The lack of a side chain facilitates packing against other amino acids with bulkier side groupings, as well as against other gly- cines to promote helix interactions. Possibly, increased residue volume associated with the G23V mutation pro- motes steric clashes that impair protein topology or confor- mational changes responsible for substrate translocation as shown for glycine-to-valine substitutions in other pumps/ transporters (3,13), such as observed here with this partic- ular mutation in hTHTR2 (Fig. 2D). More generally, this initial region of SLC19A polypeptides seems to have low functional tolerance to mutation: a P51L mutation in hTHTR1 (P33 in hTHTR2, distal to TM1) is associated with thiamine- responsive megaloblastic anemia (23, 36). ...
The water-soluble micronutrient thiamine is required for normal tissue growth and development in humans. Thiamine is accumulated into cells through the activity of two cell surface thiamine transporters (hTHTR1 and hTHTR2), which are differentially targeted in polarized tissues. Mutational dysfunction of hTHTR1 is associated with the clinical condition of thiamine-responsive megaloblastic anemia: the symptoms of which are alleviated by thiamine supplementation. Recently, two hTHTR2 mutants (G23V, T422A) have been discovered in clinical kindreds manifesting biotin-responsive basal ganglia disease (BBGD): the symptoms of which are alleviated by biotin administration. Why then does mutation of a specific thiamine transporter isoform precipitate a disorder correctable by exogenous biotin? To investigate the suggestion that hTHTR2 can physiologically function as a biotin transporter, we examined 1) the cell biological basis of hTHTR2 dysfunction associated with the G23V and T422A mutations and 2) the substrate specificity of hTHTR2 and these clinically relevant mutants. We show that the G23V and T422A mutants both abrogate thiamine transport activity rather than targeting of hTHTR2 to the cell surface. Furthermore, biotin accumulation was not detectable in cells overexpressing either the full length hTHTR2 or the clinically relevant hTHTR2 mutants, yet was demonstrable in the same assay using cells overexpressing the human sodium-dependent multivitamin transporter, a known biotin transporter. These results cast doubt on the most parsimonious explanation for the BBGD phenotype, namely that hTHTR2 is a physiological biotin transporter.
... RSO membrane vesicles containing single-Cys replacements of C-less LacY at position 2, 3,4,5,8,11,12,15,21,22,25,27,29,30,32,34,42,44,70,71,81,84,86,87,88 Reactions were terminated at the indicated time by adding 10 mM DTT. The membranes were then solubilized in 50 mM NaP i (pH 7.5)/2% n-dodecyl β-D-maltopyranoside (DDM). ...
Previous N-ethylmaleimide-labeling studies show that ligand binding increases the reactivity of single-Cys mutants located predominantly on the periplasmic side of LacY and decreases reactivity of mutants located for the most part of the cytoplasmic side. Thus, sugar binding appears to induce opening of a periplasmic pathway with closing of the cytoplasmic cavity resulting in alternative access of the sugar-binding site to either side of the membrane. Here we describe the use of a fluorescent alkylating reagent that reproduces the previous observations with respect to sugar binding. We then show that generation of an H(+) electrochemical gradient (Delta(mu (H)+), interior negative) increases the reactivity of single-Cys mutants on the periplasmic side of the sugar-binding site and in the putative hydrophilic pathway. The results suggest that Delta(mu (H)+), like sugar, acts to increase the probability of opening on the periplasmic side of LacY.
Iron is an indispensable metabolic cofactor in both pro- and eukaryotes, which engenders a natural competition for the metal between bacterial pathogens and their human or animal hosts. Bacteria secrete siderophores that extract Fe3+ from tissues, fluids, cells, and proteins; the ligand gated porins of the Gram-negative bacterial outer membrane actively acquire the resulting ferric siderophores, as well as other iron-containing molecules like heme. Conversely, eukaryotic hosts combat bacterial iron scavenging by sequestering Fe3+ in binding proteins and ferritin. The variety of iron uptake systems in Gram-negative bacterial pathogens illustrates a range of chemical and biochemical mechanisms that facilitate microbial pathogenesis. This document attempts to summarize and understand these processes, to guide discovery of immunological or chemical interventions that may thwart infectious disease.
Several different methodologies for mutagenesis have been developed to introduce mutations at predetermined sites or regions within mammalian genes. These methods of in vitro mutagenesis have had a transforming effect on the understanding of functions of protein, transcription regulatory elements, and noncoding RNAs and are now integral to molecular biology investigations. In this introduction, we summarize the most commonly used experimental approaches for mutagenesis and their major applications.
Plasmids encoding “split” lactose permease constructs with discontinuities in either the periplasmic loop between helices V and VI (N5/C7) or between helices VI and VII (N6/C6) were used to localize helix VI within the tertiary structure by site-directed thiol cross-linking. A total of 57 double-Cys pairs, with one Cys residue in helix VI and another in helix V or VIII, were studied with homobifunctional cross-linking agents. Significant cross-linking is observed between the periplasmic ends of helices V (position 158 or 161) and VI (position 170) with rigid 6 or 10 Å reagents. Furthermore, the Cys residue at position 170 (helix VI) also cross-links to a Cys residue at either position 264 or 265 (helix VIII) with a 21 Å cross-linking agent. The data indicate that helices V, VI and VIII are in close proximity at the periplasmic face of the membrane, with helix VI significantly closer to helix V. In addition, β,d-galactopyranosyl 1-thio-β,d-galactopyranoside induces a significant increase in cross-linking efficiency between helices VI and VIII and between helices V and VIII, with no significant change in cross-linking between helices V and VI.
A mechanism for the coupled translocation of substrate and H+ by the lactose permease of Escherichia coli is proposed, based on a variety of experimental observations. The permease is composed of 12 alpha-helical rods that traverse the membrane with the N and C termini on the cytoplasmic face. Four residues are irreplaceable with respect to coupling, and the residues are paired-Arg-302 (helix IX) with Glu-325 (helix X) and His-322 (helix X) with Glu-269 (helix VIII). In an adjacent region of the molecule at the interface between helices VIII and V is the substrate translocation pathway. Because of this arrangement, interfacial changes between helices VIII and V are transmitted to the interface between helices IX and X and vice versa. Upon ligand binding, a structural change at the interface between helices V and VIII disrupts the interaction between Glu-269 and His-322, Glu-269 displaces Glu-325 from Arg-302, and Glu-325 is protonated. Simultaneously, protonated Glu-325 becomes inaccessible to water, which drastically increases its pKa. In this configuration, the permease undergoes a freely reversible conformational change that corresponds to translocation of the ternary complex. To return to ground state after release of substrate, the Arg-302-Glu-325 interaction must be reestablished, which necessitates loss of H+ from Glu-325. The H+ is released into a water-filled crevice between helices IX and X which becomes transiently accessible to both sides of the membrane due to a change in helix tilt, where it is acted upon equally by either the membrane potential or the pH gradient across the membrane.
The entire lactose permease of Escherichia coli, a polytopic membrane transport protein that catalyzes beta-galactoside/H+ symport, has been subjected to Cys-scanning mutagenesis in order to determine which residues play an obligatory role in the mechanism and to create a library of mutants with a single-Cys residue at each position of the molecule for structure/function studies. Analysis of the mutants has led to the following: 1) only six amino acid side chains play an irreplaceable role in the transport mechanism; 2) positions where the reactivity of the Cys replacement is increased upon ligand binding are identified; 3) positions where the reactivity of the Cys replacement is decreased by ligand binding are identified; 4) helix packing, helix tilt, and ligand-induced conformational changes are determined by using the library of mutants in conjunction with a battery of site-directed techniques; 5) the permease is a highly flexible molecule; and 6) a working model that explains coupling between beta-galactoside and H+ translocation. structure-function relationships in polytopic membrane proteins.
The nature and distribution of amino acids in the helix interfaces of four polytopic membrane proteins (cytochrome c oxidase, bacteriorhodopsin, the photosynthetic reaction center of Rhodobacter sphaeroides, and the potassium channel of Streptomyces lividans) are studied to address the role of glycine in transmembrane helix packing. In contrast to soluble proteins where glycine is a noted helix breaker, the backbone dihedral angles of glycine in transmembrane helices largely fall in the standard alpha-helical region of a Ramachandran plot. An analysis of helix packing reveals that glycine residues in the transmembrane region of these proteins are predominantly oriented toward helix-helix interfaces and have a high occurrence at helix crossing points. Moreover, packing voids are generally not formed at the position of glycine in folded protein structures. This suggests that transmembrane glycine residues mediate helix-helix interactions in polytopic membrane proteins in a fashion similar to that seen in oligomers of membrane proteins with single membrane-spanning helices. The picture that emerges is one where glycine residues serve as molecular notches for orienting multiple helices in a folded protein complex.
We studied the effect of pH on ligand binding in wild-type lactose permease or mutants in the four residues-Glu-269, Arg-302, His-322, and Glu-325-that are the key participants in H(+) translocation and coupling between sugar and H(+) translocation. Although wild-type permease or mutants in Glu-325 and Arg-302 exhibit marked decreases in affinity at alkaline pH, mutants in either His-322 or Glu-269 do not titrate. The results offer a mechanistic model for lactose/H(+) symport. In the ground state, the permease is protonated, the H(+) is shared between His-322 and Glu-269, Glu-325 is charge-paired with Arg-302, and substrate is bound with high affinity at the outside surface. Substrate binding induces a conformational change that leads to transfer of the H(+) from His-322/Glu-269 to Glu-325 and reorientation of the binding site to the inner surface with a decrease in affinity. Glu-325 then is deprotonated on the inside because of rejuxtaposition with Arg-302. The His-322/Glu-269 complex then is reprotonated from the outside surface to reinitiate the cycle.
To complete a study on site-directed alkylation of Cys replacements in the lactose permease of Escherichia coli (LacY), the reactivity of single-Cys mutants in helices I, III, VI, and XI, as well as some of the adjoining loops, with N-[14C]ethylmaleimide (NEM) or methanethiosulfonate ethylsulfonate (MTSES) was studied in right-side-out membrane vesicles. With the exception of several positions in the middle of helix I, which either face the bilayer or are in close proximity to other helices, the remaining Cys replacements react with the membrane-permeant alkylating agent NEM. In helices III and XI, most Cys replacements are also alkylated by NEM except for positions that face the bilayer. The reactivity of Cys replacements in helix VI is noticeably lower and only 45% of the replacements label. Binding of sugar leads to significant increases in the reactivity of Cys residues that are located primarily at the same level as the sugar-binding site or in the periplasmic half of each helix. Remarkably, studies with small, impermeant MTSES show that single-Cys replacements in the cytoplasmic portions of helices I and XI, which line the inward-facing cavity, are accessible to solvent from the periplasmic surface of the membrane. Moreover, addition of ligand results in increased accessibility of Cys residues to the aqueous milieu in the periplasmic region of the helices, which may reflect structural rearrangements leading to opening of an outward-facing cavity. The findings are consistent with the X-ray structure of LacY and with the alternating access model [Abramson, J., Smirnova, I., et al. (2003) Science 301, 610-615].
Building a three-dimensional model of the sucrose permease of Escherichia coli (CscB) with the X-ray crystal structure lactose permease (LacY) as template reveals a similar overall fold for CscB. Moreover, despite only 28% sequence identity and a marked difference in substrate specificity, the structural organization of the residues involved in sugar-binding and H(+) translocation is conserved in CscB. Functional analyses of mutants in the homologous key residues provide strong evidence that they play a similar critical role in the mechanisms of CscB and LacY.
The lactose permease of Escherichia coli (LacY) is a highly dynamic membrane transport protein, while the Cys154-->Gly mutant is crippled conformationally. The mutant binds sugar with high affinity, but catalyzes very little translocation across the membrane. In order to further investigate the defect in the mutant, fluorescent maleimides were used to examine the accessibility/reactivity of single-Cys LacY in right-side-out membrane vesicles. As shown previously, sugar binding induces an increase in reactivity of single-Cys replacements in the tightly packed periplasmic domain of wild-type LacY, while decreased reactivity is observed on the cytoplasmic side. Thus, the predominant population of wild-type LacY in the membrane is in an inward-facing conformation in the absence of sugar, sugar binding induces opening of a hydrophilic pathway on the periplasmic side, and the sugar-binding site is alternatively accessible to either side of the membrane. In striking contrast, the accessibility/reactivity of periplasmic Cys replacements in the Cys154-->Gly background is very high in the absence of sugar, and sugar binding has little or no effect. The observations indicate that an open hydrophilic pathway is present on the periplasmic side of the Cys154-->Gly mutant and that this pathway is unaffected by ligand binding, a conclusion consistent with findings obtained from single-molecule fluorescence and double electron-electron resonance.
The previously described hybrid plasmid pC7 which carries lacI+ O+Δ(Z)Y+ A+ on a 12.3 × 106-Mr DNA fragment [Teather et al. (1978) Mol. Gen. Genet. 159, 239–248] was partially digested with the restriction endonuclease EcoRI under conditions reducing the recognition sequence to ↓ d(A-A-T-T) and ligated to the vector pBR322. lacY-carrying inserts of various sizes (Mr, 1.5–4.7 × 106) were obtained.
Hybrid plasmid pTE18 (2300-base-pair insert) carries part of the I (repressor) gene, the promotor-operator region, part of the Z (β-galactosidase) gene, the Y (lactose carrier) gene and part of the A (transacetylase) gene. Upon induction of pTE18-harbouring strains the Y-gene product is expressed at a nearly constant rate for several generations and accumulates to a level of 12–16% of the total cytoplasmic membrane protein. Integration into the membrane leads to active carrier as judged by binding and transport measurements.
The Escherichia coli strain carrying the lac Y54-41 gene encodes a mutant lactose permease which carries out normal downhill transport of galactosides but is defective in uphill accumulation. In this study, the mutant lac Y54-41 gene was cloned onto the multicopy vector pUR270. As expected, the cloned gene was shown to express normal downhill transport activity but was markedly defective in the uphill transport of methyl-beta-D-thiogalactopyranoside. Direct measurements of H+ transport revealed that the mutant permease can transport H+ with methyl-beta-D-thiogalactopyranoside but at a significantly reduced capacity compared to the wild-type strain. However, under conditions where the mutant and wild-type strains both transport lactose at similar rates, no detectable H+ transport was observed in the mutant strain. The entire cloned lac Y54-41 gene was subjected to DNA sequencing, and a single base substitution was found which replaces glycine 262 in the protein with a cysteine residue. Inhibition experiments showed that the mutant permease is dramatically more sensitive to three different sulfhydryl reagents: N-ethylmaleimide, p-hydroxymericuribenzoate, and p-hydroxymercuriphenylsulfonic acid. However, the lactose analogue, thiodigalactoside, was only marginally effective at protecting against inhibition in the mutant strain. The results are consistent with the idea that the sulfhydryl reagents are inhibiting the mutant permease activity by reacting with cysteine 262.
A dodecapeptide corresponding to the carboxyl terminus of the lac carrier of Escherichia coli was synthesized, coupled to thyroglobulin, and the conjugate was used to generate site-directed polyclonal antibodies. The antibodies react with the carboxyl-terminal peptide and with the lac carrier protein, while monoclonal antibody 4B1 reacts with intact lac carrier protein, but not with the carboxyl-terminal peptide. Antibody 4B1 binds preferentially to right-side-out membrane vesicles relative to inside-out vesicles, confirming the presence of the 4B1 epitope on the periplasmic surface of the membrane. Alternatively, anti-carboxyl-terminal antibody binds preferentially to inside-out vesicles, demonstrating that the carboxyl terminus of the lac carrier protein is on the cytoplasmic surface. Surprisingly, both antibodies bind to proteoliposomes reconstituted with purified lac carrier protein, and quantitative binding assays indicate that the epitopes are equally accessible. When proteoliposomes containing purified lac carrier protein are digested with carboxypeptidases A and B, binding of anti-carboxyl-terminal antibodies decreases by greater than 80%, while binding of antibody 4B1 and various transport activities remain essentially unchanged. It is suggested that during reconstitution, the lac carrier protein undergoes intramolecular dislocation of the carboxyl terminus with no significant effect on its catalytic activity.
The lactose carrier protein of Escherichia coli was purified by a simple procedure employing differential solubilization and ion-exchange chromatography and reconstituted into liposomes by octylglucoside dilution. The proteoliposomes exhibited both membrane potential-driven lactose transport and lactose counterflow. Furthermore, the purified protein was identified as the product of the lac y gene. These and other results demonstrate that the lactose carrier is the only polypeptide species essential for energy-coupled lactose transport and counterflow.
A conserved motif, GXXX(D/E)(R/K)XG(R/K)(R/K), has been identified among a large group of evolutionarily related membrane proteins involved in the transport of small molecules across the membrane. To determine the importance of this motif within the lactose permease of Escherichia coli, a total of 28 site-directed mutations at the conserved first, fifth, sixth, eighth, ninth, and tenth positions were analyzed. A dramatic inhibition of activity was observed with all bulky mutations at the first-position glycine. Based on these results, together with sequence comparisons within the superfamily, it seems likely that small side chain volume (and possibly high beta-turn propensity) may be structurally important at this position. The acidic residue at the fifth position was also found to be very important for transport activity and even a conservative glutamate at this location exhibited marginal transport activity. In contrast, many substitutions at the eighth-position glycine, even those with a high side chain volume and/or low beta-turn propensity, still retained high levels of transport activity. Similarly, none of the basic residues within the motif were essential for transport activity when replaced individually by nonbasic residues. However, certain substitutions at the basic residue sites as well as the eighth-position glycine were observed to have moderately reduced levels of active transport of lactose. Taken together, the results of this study confirm the importance of the conserved loop 2/3 motif in transport function. It is suggested that this motif may be important in promoting global conformational changes within the permease.
The lactose permease (lac) of Escherichia coli is a paradigm for membrane transport proteins. Encoded by the lacY gene, the permease has been solubilized, purified to homogeneity, reconstituted into phospholipid vesicles and shown to catalyse the coupled translocation of beta-galactosides and H+ with a stoichiometry of unity. Circular dichroism and other spectroscopic approaches demonstrate that the purified permease is about 80% helical. Based on hydropathy analysis of the primary amino-acid sequence, a secondary structure has been proposed in which the protein has 12 hydrophobic domains in alpha-helical conformation that traverse the membrane in zigzag fashion connected by hydrophilic loops. A variety of other approaches are consistent with the model and demonstrate that both the N and C termini are on the inner surface of the membrane, and studies on an extensive series of lac permease/alkaline phosphatase fusion proteins provide exclusive support for the topological predictions of the 12-helix motif. This presentation concentrates on the use of site-directed fluorescence spectroscopy to study structure-function relationships in the permease.
Acidic residues which are found on transmembrane segments within the lactose permease may play an important role in H+ and/or sugar recognition. To examine the functional roles of Glu-269 and Glu-325, we have constructed a variety of amino acid substitutions (e.g. aspartate, glycine, alanine, serine, or glutamine) via site-directed mutagenesis. At position 269, all mutations appear to have a detrimental effect on sugar affinity, downhill transport, and counterflow. The Asp-269 mutant was able to accumulate lactose against a concentration gradient, whereas all of the nonionizable substitutions at position 269 were completely defective. Nevertheless, in spite of their inability to actively accumulate sugars, Gly-269, Ala-269, and Gln-269 mutants were observed to transport H+ upon the addition of galactosides. Mutations at position 325 had a markedly different phenotype. For example, the Asp-325, Gly-325, and Gln-325 mutants exhibited an apparent Km for lactose transport (e.g. 0.21, 0.47, and 0.50 mM, respectively), which was actually lower than that of the wild-type strain (1.44 mM). In counterflow assays, all position 325 mutants also appear to catalyze lactose exchange. Similar to the results obtained at position 269, the Asp-325 mutant exhibited moderate levels of accumulation, whereas none of the nonionizable mutations at position 325 were able to accumulate galactosides against a concentration gradient. However, unlike the position 269 mutants, no H+ transport was observed in the Gly-325, Ala-325, Ser-325, or Gln-325 strains upon the addition of lactose, S-beta-D-galactopyranosyl-(1,1)-beta-thiogalactopyranoside, 1-O-methyl-beta-D-galactopyranoside, or melibiose. Furthermore, in these mutants, the efflux of lactose during counterflow assays became insensitive to delta pH. Overall, these results are consistent with the notion that an acidic residue at position 325 is required for H+ transport via the lactose permease. Alternative hypotheses are also discussed.
A conserved motif, GXXX(D/E)(R/K)XG(R/K)(R/K), has been identified among a large group of evolutionarily related membrane proteins involved in the transport of small molecules across the membrane. To determine the importance of this motif within the lactose permease of Escherichia coli, a total of 28 site-directed mutations at the conserved first, fifth, sixth, eighth, ninth, and tenth positions were analyzed. A dramatic inhibition of activity was observed with all bulky mutations at the first-position glycine. Based on these results, together with sequence comparisons within the superfamily, it seems likely that small side chain volume (and possibly high beta-turn propensity) may be structurally important at this position. The acidic residue at the fifth position was also found to be very important for transport activity and even a conservative glutamate at this location exhibited marginal transport activity, In contrast, many substitutions at the eighth-position glycine, even those with a high side chain volume and/or low beta-turn propensity, still retained high levels of transport activity. Similarly, none of the basic residues within the motif were essential for transport activity when replaced individually by nonbasic residues. However, certain substitutions at the basic residue sites as well as the eighth-position glycine were observed to have moderately reduced levels of active transport of lactose, Taken together, the results of this study confirm the importance of the conserved loop 2/3 motif in transport function. It is suggested that this moth may be important in promoting global conformational changes within the permease.
Using a functional lactose permease mutant devoid of Cys residues (C-less permease), each amino acid in putative transmembrane helix XI was individually replaced with Cys (from Ala347 to Ser366). Fifteen of the 20 mutants are highly functional and accumulate lactose to >60% of the level achieved by C-less permease, and an additional three mutants, all located at the cytoplasmic end of the helix, exhibit lower but significant lactose accumulation. Cys replacements for Thr348 or Lys358 result in virtually inactive permease. Lys358, however, is not essential for active lactose transport but plays a role in permease folding or membrane insertion by interacting with Asp237. Immunoblots reveal that all mutant proteins are present in the membrane in amounts comparable to C-less with the exception of Lys358→Cys which is hardly detectable, as expected. The results highlight Thr348 as a potentially important residue for further analysis. Finally, all active mutants were assayed after treatment with the sulfhydryl reagent N-ethylmaleimide, and results range from nearly complete inhibition to almost 2-fold stimulation. Remarkably, all of the strongly inhibited positions lie on one face of helix XI. The implications of the findings for packing of transmembrane helices in the C-terminal half of the permease are discussed.
The lac permease of Escherichia coli is providing a paradigm for secondary active transporter proteins that transduce the free energy stored in electrochemical ion gradients into work in the form of a concentration gradient. This hydrophobic, polytopic, cytoplasmic membrane protein catalyzes the coupled, stoichiometric translocation of β-galactosides and H⁺, and it is solubilized, purified, reconstituted into artificial phospholipid vesicles and is responsible for β-galactoside transport as a monomer. The lacY gene that encodes the permease is cloned and sequenced and is based on spectroscopic analyses of the purified protein and hydropathy profiling of its amino-acid sequence. A secondary structure is proposed in which the protein has 12 transmembrane domains in α-helical configuration that traverse the membrane in zigzag fashion connected by hydrophilic loops with the N and C termini on the cytoplasmic face of the membrane. Unequivocal support for the topological predictions of the 12-helix model is obtained by analyzing a large number of lac permease-alkaline phosphatase (lacY-phoA) fusions. Extensive use of site-directed and Cys-scanning mutagenesis indicates that very few residues in the permease are directly involved in the transport mechanism.
Six single-Trp mutants were engineered by individually reintroducing each of the native Trp residues into a functional lactose permease mutant devoid of Trp (Trp-less permease; Menezes ME, Roepe PD, Kaback HR, 1990, Proc Natl Acad Sci USA 87:1638–1642), and fluorescent properties were studied with respect to solvent accessibility, as well as alterations produced by ligand binding. The emission of Trp 33, Trp 78, Trp 171, and Trp 233 is strongly quenched by both acrylamide and iodide, whereas Trp 151 and Trp 10 display a decrease in fluorescence in the presence of acrylamide only and no quenching by iodide. Of the six single-Trp mutants, only Trp 33 exhibits a significant change in fluorescence (ca. 30% enhancement) in the presence of the substrate analog β,D-galactopyranosyl 1-thio-β,D-galactopyranoside (TDG). This effect was further characterized by site-directed fluorescent studies with purified single-Cys W33 → C permease labeled with 2-(4′-maleimidylanilino)-naphthalene-6-sulfonic acid (MIANS). Titration of the change in the fluorescence spectrum reveals a 30% enhancement accompanied with a 5-nm blue shift in the emission maximum, and single exponential behavior with an apparent KD of 71 μM. The effect of substrate binding on the rate of MIANS labeling of single-Cys 33 permease was measured in addition to iodide and acrylamide quenching of the MIANS-labeled protein. Complete blockade of labeling is observed in the presence of TDG, as well as a 30% decrease in accessibility to iodide with no change in acrylamide quenching. Overall, the findings are consistent with the proposal (Wu J, Frillingos S, Kaback HR, 1995a, Biochemistry 34:8257–8263) that ligand binding induces a conformational change at the C-terminus of helix I such that Pro 28 and Pro 31, which are on one face, become more accessible to solvent, whereas Trp 33, which is on the opposite face, becomes less accessible to the aqueous phase. The findings regarding accessibility to collisional quenchers are also consistent with the predicted topology of the six native Trp residues in the permease.
Using a functional lactose permease mutant devoid of Cys residues (C-less permease), each amino-acid residue in putative transmembrane helices IX and X and the short intervening loop was systematically replaced with Cys (from Asn-290 to Lys-335). Thirty-four of 46 mutants accumulate lactose to high levels (70-100% or more of C-less), and an additional 7 mutants exhibit lower but highly significant lactose accumulation. As expected (see Kaback, H.R., 1992, Int. Rev. Cytol. 137A, 97-125), Cys substitution for Arg-302, His-322, or Glu-325 results in inactive permease molecules. Although Cys replacement for Lys-319 or Phe-334 also inactivates lactose accumulation, Lys-319 is not essential for active lactose transport (Sahin-Tóth, M., Dunten, R.L., Gonzalez, A., & Kaback, H.R., 1992, Proc. Natl. Acad. Sci. USA 89, 10547-10551), and replacement of Phe-334 with leucine yields permease with considerable activity. All single-Cys mutants except Gly-296 → Cys are present in the membrane in amounts comparable to C-less permease, as judged by immunological techniques. In contrast, mutant Gly-296 → Cys is hardly detectable when expressed at a relatively low rate from the lac promoter/operator but present in the membrane in stable form when expressed at a high rate from the T7 promoter. Finally, studies with N-ethylmaleimide (NEM) show that only a few mutants are inactivated significantly. Remarkably, the rate of inactivation of Val-315 → Cys permease is enhanced at least 10-fold in the presence of β-galactopyranosyl 1-thio-β,d-galactopyranoside (TDG) or an H+ electrochemical gradient (Δ). The results demonstrate that only three residues in this region of the permease–Arg-302, His-322, and Glu-325–are essential for active lactose transport. Furthermore, the enhanced reactivity of the Val-315 → Cys mutant toward NEM in the presence of TDG or Δ probably reflects a conformational alteration induced by either substrate binding or Δ.
The dideoxy sequencing method in which denatured plasmid DNA is used as a template was improved. The method is simple and rapid: the recombinant plasmid DNA is extracted and purified by rapid alkaline lysis followed by ribonuclease treatment. The plasmid DNA is then immediately denatured with alkali and subjected to a sequencing reaction utilizing synthetic oligonucleotide primers. It takes only several hours from the start of the plasmid extraction to the end of the sequencing reaction. We examined each step of the procedure, and several points were found to be crucial for making the method reproducible and powerful: (i) the plasmid DNA should be free from RNA and open circular (or linear) DNA; (ii) a heptadecamer rather than a pentadecamer is recommended as a primer; and (iii) the sequencing reaction should be done at 37°C or higher rather than at room temperature. The method enabled us to determine the sequence of more than a thousand nucleotides from a single template DNA.
A new method for determining nucleotide sequences in DNA is described. It is similar to the "plus and minus" method [Sanger, F. & Coulson, A. R. (1975) J. Mol. Biol. 94, 441-448] but makes use of the 2',3'-dideoxy and arabinonucleoside analogues of the normal deoxynucleoside triphosphates, which act as specific chain-terminating inhibitors of DNA polymerase. The technique has been applied to the DNA of bacteriophage varphiX174 and is more rapid and more accurate than either the plus or the minus method.
Some recent modifications of the protein assay by the method of Lowry, Rosebrough, Farr, and Randall (1951, J. Biol. Chem.193, 265–275) have been reexamined and altered to provide a consolidated method which is simple, rapid, objective, and more generally applicable. A DOC-TCA protein precipitation technique provides for rapid quantitative recovery of soluble and membrane proteins from interfering substances even in very dilute solutions (< 1 μg/ml of protein). SDS is added to alleviate possible nonionic and cationic detergent and lipid interferences, and to provide mild conditions for rapid denaturation of membrane and proteolipid proteins. A simple method based on a linear log-log protein standard curve is presented to permit rapid and totally objective protein analysis using small programmable calculators. The new modification compared favorably with the original method of Lowry et al.
Using a lactose permease mutant devoid of Cys residues ('C-less permease'), we systematically replaced putative intramembrane charged residues with Cys. Individual replacements for Asp-237, Asp-240, Glu-269, Arg-302, Lys-319, His-322, Glu-325, or Lys-358 abolish active lactose transport. When Asp-237 and Lys-358 are simultaneously replaced with Cys and/or Ala, however, high activity is observed. Therefore, when either Asp- 237 or Lys-358 is replaced with a neutral residue, leaving an unpaired charge, the permease is inactivated, but neutral replacement of both residues yields active permease [King, S. C., Hansen, C. L. and Wilson, T. H. (1991) Biochim. Biophys. Acta 1062, 177-186]. Remarkably, moreover, when Asp-237 is interchanged with Lys-358, high activity is observed. The observations provide a strong indication that Asp-237 and Lys-358 interact to form a salt bridge. In addition, the data demonstrate that neither residue nor the salt bridge plays an important role in the transport mechanism. Thirteen additional double mutants were constructed in which a negative and positively charged residue were replaced with Cys. Only Asp-240 → Cys/Lys-319 → Cys exhibits significant activity, accumulating lactose to 25-30% of the steady state observed with C-less permease. Replacing either Asp-240 or Lys-319 individually with Ala also inactivates the permease, but double mutants with neutral substitutions (Cys and/or Ala) at both positions exhibit essentially the same activity as Asp-240 → Cys/Lys-319 → Cys. In marked contrast to As lactose transport. The results demonstrate that Asp-240 and Lys-319, like Asp-237 and Lys-358, interact functionally and may form a salt bridge. However, the interaction between Asp-240 and Lys-319 is clearly more complex than the interaction between Asp-237 and Lys-358. In any event, the findings suggest that putative transmembrane helix VII lies next to helices X and XI in the tertiary structure of lactose permease.
The lactose permease of Escherichia coli is a membrane transport protein postulated to contain a hydrophilic N terminus (hydrophilic domain 1), 12 hydrophobic transmembrane alpha-helices that traverse the membrane in zigzag fashion connected by hydrophilic domains, and a hydrophilic C terminus (hydrophilic domain 13). To test whether the hydrophilic domains are important for function, each domain was independently disrupted by insertion of two or six contiguous histidine residues, and the mutants were characterized with respect to initial rate of lactose transport and steady-state level of accumulation. Remarkably, histidine insertions into 10 out of 13 hydrophilic domains result in molecules that catalyze lactose accumulation effectively, although the initial rate of transport is compromised in certain cases. In contrast, insertions into hydrophilic domain 3, 9, or 10 cause a marked decrease in transport activity. As judged by immunoblots and [35S]methionine pulse-chase experiments, diminished activity is not due to decreased expression of the mutated permeases, defective insertion into the membrane, or increased rates of proteolysis after insertion. The results (i) suggest that most of the hydrophilic domains in the permease do not play an essential role in the transport mechanism and (ii) focus on the region of the permease containing putative helices IX and X as being particularly important for activity.
When the lactose (lac) permease of Escherichia coli is expressed from the lac promoter at relatively low rates, deletion of amino acid residues 2-8 (delta 7) or 2-9 (delta 8) from the hydrophilic N terminus has a relatively minor effect on the ability of the permease to catalyze active lactose transport. Activity is essentially abolished, however, and the permease is hardly detected in the membrane when two additional amino acid residues are deleted (delta 10), and mutants deleted of residues 2-23 (delta 22) or 2-39 (delta 38) also exhibit no activity and are not inserted into the membrane. Dramatically, when the defective deletion mutants are overexpressed at high rates via the T7 promoter, delta 10 and delta 22 are inserted into the membrane in a stable form and catalyze active lactose transport in a highly significant manner, whereas delta 38 is hardly detected in the membrane and exhibits no activity. Interestingly, a fusion protein consisting of delta 38 and the ompA leader peptide is inserted into the membrane but exhibits no transport activity. The results indicate that the N-terminal hydrophilic domain of lac permease and the N-terminal half of the first putative transmembrane alpha-helix are not mandatory for either membrane insertion or transport activity.
The overall topology of polytopic membrane proteins is thought to result from either the oriented insertion of the N-terminal alpha-helical domain followed by passive insertion of subsequent helices or from the function of independent topogenic determinants dispersed throughout the molecules. By using the lactose permease of Escherichia coli, a well-characterized membrane protein with 12 transmembrane domains and the N and C termini on the cytoplasmic surface of the membrane, we have studied the insertion and stability of in-frame deletion mutants. So long as the first N-terminal and the last four C-terminal putative alpha-helical domains are retained, stable polypeptides are inserted into the membrane, even when an odd number of helical domains is deleted. Moreover, even when an odd number of helices is deleted, the C terminus remains on the cytoplasmic surface of the membrane, as judged by lacY-phoA fusion analysis. In addition, permease molecules devoid of even or odd numbers of putative transmembrane helices retain a specific pathway for downhill lactose translocation. The findings imply that relatively short C-terminal domains of the permease contain topological information sufficient for insertion in the native orientation regardless of the orientation of the N terminus.
By use of oligonucleotide-directed, site-specific mutagenesis, a lactose (lac) permease molecule was constructed in which all eight cysteinyl residues were simultaneously mutagenized (C-less permease). Cys154 was replaced with valine, and Cys117, -148, -176, -234, -333, -353, and -355 were replaced with serine. Remarkably, C-less permease catalyzes lactose accumulation in the presence of a transmembrane proton electrochemical gradient (interior negative and alkaline). Thus, in intact cells and right-side-out membrane vesicles containing comparable amounts of wild-type and Cys-less permease, the mutant protein catalyzes lactose transport at a maximum velocity and to a steady-state level of accumulation of about 35% and 55%, respectively, of wild-type with a similar apparent Km (ca. 0.3 mM). As anticipated, moreover, active lactose transport via C-less permease is completely resistant to inactivation by N-ethylmaleimide. Finally, C-less permease also catalyzes efflux and equilibrium exchange at about 35% of wild-type activity. The results provide definitive evidence that sulfhydryl groups do not play an essential role in the mechanism of lactose/H+ symport. Potential applications of the C-less mutant to studies of static and dynamic aspects of permease structure/function are discussed.
By use of site-directed mutagenesis, each prolyl residue in the lac permease of Escherichia coli at positions 28 (putative helix I), 31 (helix I), 61 (helix II), 89 (helix III), 97 (helix III), 123 (helix IV), 192 (putative hydrophilic region 7), 220 (helix VII), 280 (helix VIII), and 327 [helix X; Lolkema, J. S., et al. (1988) Biochemistry 27, 8307] was systematically replaced with Gly, Ala, or Leu or deleted by truncation of the C-terminus [i.e., Pro403 and Pro405; Roepe, P.D., et al. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 3992]. Replacements were chosen on the basis of side-chain helical propensity: Gly, like Pro, is thought to be a "helix breaker", while Ala and Leu are "helix makers". With the exception of Pro28, each prolyl residue can be replaced with Gly or Ala, and Pro403 and -405 can be deleted with the C-terminal tail, and significant lac permease activity is retained. In contrast, when Pro28 is replaced with Gly, Ala, or Ser, lactose transport is abolished, but permease with Ser28 binds p-nitrophenyl alpha-D-galactopyranoside and catalyzes active transport of beta-galactopyranosyl-1-thio-beta-D- galactopyranoside. Replacement of Pro28, -31, -123, -280, or -327 with Leu abolishes lactose transport, while replacement of Pro61, -89, -97, or -220 with Leu has relatively minor effects. None of the alterations in permease activity is due to inability of the mutant proteins to insert into the membrane or to diminished lifetimes after insertion, since the concentration of each mutant permease in the membrane is comparable to that of wild-type permease as judged by immunological analyses.(ABSTRACT TRUNCATED AT 250 WORDS)
The cell membranes of various bacteria contain proton-linked transport systems for D-xylose, L-arabinose, D-galactose, D-glucose, L-rhamnose, L-fucose, lactose, and melibiose. The melibiose transporter of E. coli is linked to both Na+ and H+ translocation. The substrate and inhibitor specificities of the monosaccharide transporters are described. By locating, cloning, and sequencing the genes encoding the sugar/H+ transporters in E. coli, the primary sequences of the transport proteins have been deduced. Those for xylose/H+, arabinose/H+, and galactose/H+ transport are homologous to each other. Furthermore, they are just as similar to the primary sequences of the following: glucose transport proteins found in a Cyanobacterium, yeast, alga, rat, mouse, and man; proteins for transport of galactose, lactose, or maltose in species of yeast; and to a developmentally regulated protein of Leishmania for which a function is not yet established. Some of these proteins catalyze facilitated diffusion of the sugar without cation transport. From the alignments of the homologous amino acid sequences, predictions of common structural features can be made: there are likely to be twelve membrane-spanning alpha-helices, possibly in two groups of six; there is a central hydrophilic region, probably comprised largely of alpha-helix; the highly conserved amino acid residues (40-50 out of 472-522 total) form discrete patterns or motifs throughout the proteins that are presumably critical for substrate recognition and the molecular mechanism of transport. Some of these features are found also in other transport proteins for citrate, tetracycline, lactose, or melibiose, the primary sequences of which are not similar to each other or to the homologous series of transporters. The glucose/Na+ transporter of rabbit and man is different in primary sequence to all the other sugar transporters characterized, but it is homologous to the proline/Na+ transporter of E. coli, and there is evidence for its structural similarity to glucose/H+ transporters in Plants. In vivo and in vitro mutagenesis of the lactose/H+ and melibiose/Na+ (H+) transporters of E. coli has identified individual amino acid residues alterations of which affect sugar and/or cation recognition and parameters of transport. Most of the bacterial transport proteins have been identified and the lactose/H+ transporter has been purified. The directions of future investigations are discussed.
Mutants in putative helix VIII of lactose permease that retain the ability to accumulate lactose were created by cassette mutagenesis. A mutagenic insert encoding amino acid residues 259-278 was synthesized chemically by using reagents contaminated with 1% each of the other three bases and ligated into a KpnI/BclI site in the lacY gene in plasmid pGEM-4. Mutants that retain transport activity were selected by transforming a strain of Escherichia coli containing a wild-type lacZ gene, but deleted in lacY, with the mutant library and identifying colonies that transport lactose on indicator plates. Sequencing of the mutated region in lacY in 129 positive colonies reveals 43 single amino acid mutations at 26 sites and 26 multiple mutations. The variable amino acid positions are largely on one side of the putative alpha-helix, a stripe opposite Glu269. This mutable stripe of low information content is probably in contact with the membrane phospholipids.
The plasmid-borne raf operon encodes functions required for inducible uptake and utilization of raffinose by Escherichia coli. Raf functions include active transport (Raf permease), alpha-galactosidase, and sucrose hydrolase, which are negatively controlled by the Raf repressor. We have defined the order and extent of the three structural genes, rafA, rafB, and rafD; these are contained in a 5,284-base-pair nucleotide sequence. By comparisons of derived primary structures with known subunit molecular weights and an N-terminal peptide sequence, rafA was assigned to alpha-galactosidase (708 amino acids), rafB was assigned to Raf permease (425 amino acids), and rafD was assigned to sucrose hydrolase (476 amino acids). Transcription was shown to initiate 13 nucleotides upstream of rafA; a putative promoter, a ribosome-binding site, and a transcription termination signal were identified. Striking similarities between Raf permease and lacY-encoded lactose permease, revealed by high sequence conservation (76%), overlapping substrate specificities, and similar transport kinetics, suggest a common origin of these transport systems. alpha-Galactosidase and sucrose hydrolase are not related to host enzymes but have their counterparts in other species. We propose a modular origin of the raf operon and discuss selective forces that favored the given gene organization also found in the E. coli lac operon.
Overlap extension represents a new approach to genetic engineering. Complementary oligodeoxyribonucleotide (oligo) primers and the polymerase chain reaction are used to generate two DNA fragments having overlapping ends. These fragments are combined in a subsequent 'fusion' reaction in which the overlapping ends anneal, allowing the 3' overlap of each strand to serve as a primer for the 3' extension of the complementary strand. The resulting fusion product is amplified further by PCR. Specific alterations in the nucleotide (nt) sequence can be introduced by incorporating nucleotide changes into the overlapping oligo primers. Using this technique of site-directed mutagenesis, three variants of a mouse major histocompatibility complex class-I gene have been generated, cloned and analyzed. Screening of mutant clones revealed at least a 98% efficiency of mutagenesis. All clones sequenced contained the desired mutations, and a low frequency of random substitution estimated to occur at approx. 1 in 4000 nt was detected. This method represents a significant improvement over standard methods of site-directed mutagenesis because it is much faster, simpler and approaches 100% efficiency in the generation of mutant product.
A comparison has been made between the physiology and amino acid sequence of the lactose carriers of Klebsiella pneumoniae M5a1 and Escherichia coli K-12. The membrane transport of lactose was much weaker in Klebsiella than in E. coli. On the other hand o-nitrophenylgalactoside uptake by Klebsiella was distinctly greater than with E. coli. In spite of the differences in sugar transport between the two organisms, the amino acid sequences of the respective lactose carriers were remarkably similar (60% of the amino acids are identical).
A complementation analysis of host-controlled modification and restriction of DNA by Escherichia coli has been carried out by examining the restriction and modification phenotypes of partial, permanent diploids containing various arrangements of wild type and mutant restriction and modification alleles. Intercistronic complementation was observed between three classes of restriction and modification mutants of E. coli B, indicating that at least three cistrons (the ram cistrons) are involved in the genetic control of the [restriction and modification of DNA. Mutations in one cistron (ramA) result in a loss of restriction activity but not in modification activity (r−m+). Mutations in a second cistron (ramC) result in a loss of restriction and modification activities (r−m−). Mutations in a third cistron result in a loss of modification activity and appear to be lethal unless accompanied by a mutation in the ramA or ramC cistrons. A fourth class of mutations, which are linked to the other ram cistrons and are expressed phenotypically as r−m− mutants, are trans dominant to the wild-type ram alleles. It is not known if this latter class of mutants represents a fourth cistron of the ram locus. Complementation was observed between E. coli K12 and B ramA and ramC mutations and the host specificity of the restored restriction activity was dependent on an intact ramC cistron. However, complementation was not detected between the P1 and K12 or P1 and B ram alleles. A general model for the genetic control of the restriction and modification properties of E. coli strains and their episomes is presented.
The previously described hybrid plasmid pC7 which carries lacI+O+delta(Z)Y+A+ on a 12.3 X 10(6)-Mr DNA fragment [Teather et al. (1978) Mol. Gen. Genet. 159, 239-248] was partially digested with the restriction endonuclease EcoRI under conditions reducing the recognition sequence to d(A-A-T-T) and ligated to the vector pB322. lac Y-carrying inserts of various sized (Mr 1.5-4.7 X 10(6)) were obtained. Hybrid plasmid pTE18 (2300-base-pair insert) carries part of the I (repressor) gene, the promotor-operator region, part of the Z (beta-galactosidase) gene, the Y (lactose carrier) gene and part of the A (transacetylase) gene. Upon induction of pTE18-harbouring strains the Y-gene product is expressed at a nearly constant rate for several generations and accumulates to a level of 12-16% of the total cytoplasmic membrane protein. Integration into the membrane leads to active carrier as judged by binding and transport measurements.
Engineering divalent metal-binding sites into the lactose permease of Escherichia coli by introducing bis-His residues has been utilized to confirm the proximity of helices VIII (Glu269 --> His) and X (His322) [Jung, K., Voss, J., He, M., Hubbell, W. L., & Kaback, H. R. (1995) Biochemistry 34, 6272] and helices VII (Asp237 --> His) and XI (Lys358 --> His) [He, M. M., Voss, J., Hubbell, W. L., & Kaback, H.R. (1995) Biochemistry 34, 00000--00000]. In this paper, the approach is used to confirm and extend the relationship between helices IX (Arg302) and X (His322 and Glu325) [Jung, K., Jung, H., Wu, J., Prive, G. G., l& Kaback, H. R. (1993) Biochemistry 32, 12273]. Thus, mutants Arg302 --> His, Glu325 --> His, and Arg302 --> His/Glu325 --> His were constructed, and Mn2+ binding was assayed by electron paramagnetic resonance. Mutant Arg302 --> His binds Mn2+ with a KD of about 24 microM and a stoichiometry approximating unity in all likelihood because the His residue at position 302 forms a metal-binding site in conjunction with the native His residue at position 322. Mutant Arg302 --> His/Glu325 --> His also binds Mn2+ with a 1:1 stoichiometry, but the KD is decreased to about 13 microM. The results suggest that Arg302 is sufficiently close to both Glu325 and His322 to form a tridentate metal-binding site in mutant Arg302 --> His/Glu325 --> His. In contrast, replacement of Glu325 with His in permease with a native His residue at position 322 does not lead to Mn2+ binding. The results provide strong support for the helix packing model proposed.
The lactose permease of Escherichia coli contains two pairs of oppositely charged residues that interact functionally, Asp240 (helix VII)/Lys319 (helix X) and Asp237 (helix VII)/Lys358 (helix XI). Single- and double-His replacement mutants at these positions have been constructed and characterized with respect to transport activity and Mn2+ binding. The following results confirm the functional interactions between both sets of residues: (i) At pH 7.5, where the imidazole is likely to be unprotonated, the double-His mutants Asp237 --> His/Lys358 --> His and Asp240 --> His/Lys319 --> His exhibit significant transport activity while the single-His mutants Lys319 --> His and Lys358 --> His are inactive. (ii) At pH 5.5, where the imidazole is likely to be protonated, the double-His mutants Asp240 --> His/Lys319 --> His and Asp237 --> His/Lys358 --> His are inactive; however, the single-His mutant Lys319 --> His exhibits significant activity. (iii) The single-His mutant Asp237 --> His or ASP240 --> His is inactive at all pH values tested. In addition, a pH titration of Asp237 --> His/Lys358 --> His permease activity exhibits a midpoint at about 6.2. Finally, the purified mutant proteins Asp237 --> His/Lys358 --> His and Asp240 --> His/Lys319 --> His were assayed for Mn2+ binding by electron paramagnetic resonance spectroscopy. Asp237 --> His/Lys358 --> His permease binds Mn2+ with a stoichiometry of unity at pH 7.5, but much less binding is observed at pH 5.5, demonstrating directly that helix VII (Asp237) is in close proximity to helix XI (Lys358).(ABSTRACT TRUNCATED AT 250 WORDS)
Biotinylated lactose permease from Escherichia coli containing a single-cysteine residue at position 330 (helix X) or at position 147, 148, or 149 (helix V) was purified by avidin-affinity chromatography and derivatized with 5-(alpha-bromoacetamido)-1,10-phenanthroline-copper [OP(Cu)]. Studies with purified, OP(Cu)-labeled Leu-330 --> Cys permease in dodecyl-beta-D-maltopyranoside demonstrate that after incubation in the presence of ascorbate, cleavage products of approximately 19 and 6-8 kDa are observed on immunoblots with anti-C-terminal antibody. Remarkably, the same cleavage products are observed with permease embedded in the native membrane. Comparison with the C-terminal half of the permease expressed independently as a standard indicates that the 19-kDa product results from cleavage near the cytoplasmic end of helix VII, whereas the 6- to 8-kDa fragment probably results from fragmentation near the cytoplasmic end of helix XI. Results are entirely consistent with a tertiary-structure model of the C-terminal half of the permease derived from earlier site-directed fluorescence and site-directed mutagenesis studies. Similar studies with OP(Cu)-labeled Cys-148 permease exhibit cleavage products at approximately 19 kDa and at 15-16 kDa. The larger fragment probably reflects cleavage at a site near the cytoplasmic end of helix VII, whereas the 15- to 16-kDa fragment is consistent with cleavage near the cytoplasmic end of helix VIII. When OP(Cu) is moved 100 degrees to position 149 (Val-149 --> Cys permease), a single product is observed at 19 kDa, suggesting fragmentation at the cytoplasmic end of helix VII. However, when the reagent is moved 100 degrees in the other direction to position 147 (Gly-147 --> Cys permease), cleavage is not observed. The results suggest that helix V is in close proximity to helices VII and VIII with position 148 in the interface between the helices, position 149 facing helix VII, and position 147 facing the lipid bilayer.
Mutants with a single Cys residue in place of Phe27, Pro28, Phe29, Phe30, or Pro31 at the periplasmic end of putative transmembrane helix I were used to study the interaction of lactose permease with ligand by site-directed chemical modification or fluorescence spectroscopy. With permease embedded in the native membrane, mutant Phe27-->Cys or Phe28-->Cys is readily labeled with [14C]-N-ethylmaleimide (NEM), while mutant Phe29-->Cys, Phe30-->Cys, or Phe31-->Cys reacts less effectively. beta,D-Galactopyranosyl 1-thio-beta,D-galactopyranoside (TDG) has little or no effect on the reactivity of Phe27-->Cys, Phe29-->Cys, or Phe30-->Cys permease. Remarkably, however, Pro31-->Cys permease which is essentially unreactive in the absence of ligand becomes highly reactive in the presence of TDG. Ligand also enhances the NEM reactivity of the mutant with Cys in place of Pro28 which is presumably on the same face of helix I as position 31. The five single-Cys mutants which also contain a biotin acceptor domain in the middle cytoplasmic loop were purified by monomeric avidin-affinity chromatography in dodecyl beta,D-maltoside and subjected to site-directed fluorescence spectroscopy. Mutants Phe27-->Cys, Phe29-->Cys, and Phe30-->Cys react rapidly with 2-(4'-maleimidylanilino)naphthalene-6-sulfonic acid (MIANS), and reactivity is not altered in the presence of TDG. In striking contrast, mutants Pro28-->Cys and Pro31-->Cys react extremely slowly with MIANS in the absent of ligand, and TDG dramatically enhances reactivity.(ABSTRACT TRUNCATED AT 250 WORDS)
Using a functional lactose permease mutant devoid of Cys (C-less permease), each amino acid residue in putative transmembrane helix V was replaced individually with Cys (from Met145 to Thr163). Of the 19 mutants, 13 are highly functional (60-125% of C-less permease activity), and 4 exhibit lower but significant lactose accumulation (15-45% of C-less permease). Cys replacement of Gly147 or Trp151 essentially inactivates the permease (< 10% of C-less); however, previous studies [Menezes, M. E., Roepe, P. D., & Kaback, H. R. (1990) Proc. Natl. Acad. Sci. U.S.A. 87, 1638; Jung, K., Jung, H., et al. (1995) Biochemistry 34, 1030] demonstrate that neither of these residues is important for activity. Immunoblots reveal that all of the mutant proteins are present in the membrane in amounts comparable to C-less permease with the exception of Trp151-->Cys and single Cys154 permeases which are present in reduced amounts. Finally, only three of the single-Cys mutants are inactivated significantly by N-ethylmaleimide (Met145-->Cys, native Cys148, and Gly159-->Cys), and the positions of the three mutants fall on the same face of helix V.
Site-directed excimer fluorescence indicates that Glu269 (helix VIII) and His322 (helix X) in the lactose permease of Escherichia coli lie in close proximity [Jung, K., Jung, H., Wu, J., Privé, G.G., & Kaback, H.R. (1993) Biochemistry 32, 12273]. In this study, Glu269 was replaced with His in wild-type permease, leading to the presence of bis-His residues between helices VIII and X. Wild-type and Glu269-->His permease containing a biotin acceptor domain were purified by monomeric avidin affinity chromatography, and binding of Mn2+ was studied by electron paramagnetic resonance (EPR) spectroscopy. The amplitude of the Mn2+ EPR spectrum is reduced by the Glu269-->His mutant, while no change is observed in the presence of wild-type permease. The Glu269-->His mutant contains a single binding site for Mn2+ with a KD of about 43 microM, and Mn2+ binding is pH dependent with no binding at pH 5.0, stoichiometric binding at pH 7.5, and a midpoint at about pH 6.3. The results confirm the conclusion that helices VIII and X are closely opposed in the tertiary structure of lac permease and provide a novel approach for studying helix proximity, as well as solvent accessibility, in polytopic membrane proteins.
By using a lactose permease mutant containing a single Cys residue in place of Val 331 (helix X), conformational changes induced by ligand binding were studied. With right-side-out membrane vesicles containing Val 331-->Cys permease, lactose transport is inactivated by either N-ethylmaleimide (NEM) or 7-diethylamino-3-(4'-maleimidylphenyl)-4-methylcoumarin (CPM). Remarkably, beta,D-galactopyranosyl 1-thio-beta,D-galactopyranoside (TDG) enhances the rate of inactivation by CPM, a hydrophobic sulfhydryl reagent, whereas NEM inactivation is attenuated by the ligand. Val 331-->Cys permease was then purified and studied in dodecyl-beta,D-maltoside by site-directed fluorescence spectroscopy. The reactivity of Val 331-->Cys permease with 2-(4'-maleimidylanilino)-naphthalene-6-sulfonic acid (MIANS) is not changed over a low range of TDG concentrations (< 0.8 mM), but the fluorescence of the MIANS-labeled protein is quenched in a saturable manner (apparent Kd approximately equal to 0.12 mM) without a change in emission maximum. In contrast, over a higher range of TDG concentrations (1-10 mM), the reactivity of Val 331-->Cys permease with MIANS is enhanced and the emission maximum of MIANS-labeled permease is blue shifted by 3-7 nm. Furthermore, the fluorescence of MIANS-labeled Val 331 -->Cys permease is quenched by both acrylamide and iodide, but the former is considerably more effective. A low concentration of TDG (0.2 mM) does not alter quenching by either compound, whereas a higher concentration of ligand (10 mM) decreases the quenching constant for iodide by about 50% and for acrylamide by about 20%.(ABSTRACT TRUNCATED AT 250 WORDS)
By using oligonucleotide-directed, site-specific mutagenesis, the role of 34 Gly residues in the lactose permease of Escherichia coli has been studied systematically. Each of 34 out of a total of 36 Gly residues was replaced with Cys in a functional permease mutant devoid of Cys residues (C-less permease), as previous experiments demonstrate that Gly-402 and Gly-404 can be deleted by truncation of the C-terminus with no loss of activity [Roepe, P. D., et al. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 3992; McKenna, E., et al. (1991) Proc. Natl. Acad. Sci. U.S.A. 88, 2969]. Out of the 34 Cys-replacement mutants described, 15 transport lactose with high activity, 16 exhibit decreased but significant ability to catalyze lactose accumulation, and 3 (Gly-64-->Cys, Gly-115-->Cys and Gly-147-->Cys) exhibit no activity whatsoever. The inactive mutants were studied in more detail by replacement of Gly with Ala, Val, or Pro. C-less permease with Gly-115-->Ala or Gly-147-->Ala transports lactose almost as well as the control, while mutants with Val or Pro in place of Gly have little or no capacity to accumulate the disaccharide. In contrast, mutants with Ala, Val, or Pro in place of Gly-64 are inactive. Strikingly, however, when the mutations are placed in the wild-type background, Gly-64-->Ala permease transports lactose, beta,D-galactopyranosyl 1-thio-beta,D-galactopyranoside, and methyl 1-thio-beta,D-galactopyranoside 40-60% as well as wild-type permease, while Gly-64-->Val or Gly-64-->Pro permease is inactive toward all of these substrates. The results indicate that although none of the Gly residues in lactose permease is mandatory for activity, the bulk of the side chain at positions 64, 115, and 147, rather than conformational flexibility at these positions, is particularly important.
Glu-269, which is located on the hydrophilic face of putative helix VIII in the lactose permease of Escherichia coli, has been replaced with Asp, Gln or Cys by oligonucleotide-directed, site specific mutagenesis. Cells expressing Asp-269 permease exhibit no lactose accumulation or lactose-induced H+ translocation, but retain some ability to mediate lactose influx down a concentration gradient at high substrate concentrations. Furthermore, right-side-out membrane vesicles containing Asp-269 permease do not catalyse active lactose transport, facilitated lactose efflux or equilibrium exchange. Remarkably, however, Asp-269 permease accumulates beta, D-galactopyranosyl 1-thio-beta,D-galactopyranoside in a partially uncoupled fashion, whereas no transport of methyl-beta,D-thiogalactopyranoside, sucrose or maltose is detectable. Mutant permeases containing neutral replacements (Gln or Cys) or Glu-269 are completely devoid of activity, although the proteins are present in the membrane at concentrations comparable with wild-type or Asp-269 permease. The observations demonstrate that a carboxylate at position 269 is essential for transport activity, and Glu-269 is important for substrate binding and/or recognition.
By using site-directed fluorescence spectroscopy, we have carried out structure/function studies on lactose permease purified from Escherichia coli in dodecyl beta, D-maltoside. Initially, permease containing a single native Cys at position 148 (helix V) was studied, since this residue is protected against alkylation by substrates of the permease. In the absence of ligand, Cys 148 permease reacts rapidly with 2-(4'-maleimidylanilino)naphthalene-6-sulfonic acid (MIANS), a fluorophore whose quantum yield increases dramatically upon reaction with a thiol, indicating that this residue is readily accessible to the probe. Various ligands of the permease block the reaction, and the concentration dependence is commensurate with the affinity of each ligand for the permease (i.e., beta, D-galactopyranosyl 1-thio-beta, D-galactopyranoside < lactose < galactose), but neither sucrose nor glucose has any effect whatsoever. Thus, the permease retains the ability to bind ligand specifically when the molecule is in dodecyl beta, D-maltoside. Permease containing single Cys substitutions in the vicinity of Cys 148 was also studied. Interestingly, labeling of Cys 145 which is presumed to be one helical turn removed from Cys 148 exhibits properties similar to those observed with Cys 148 permease, but the effects of ligand are far less dramatic. On the other hand, permease with a single Cys residue at position 146 or 147 behaves in a completely different manner.(ABSTRACT TRUNCATED AT 250 WORDS)
Cys 148 in the lactose permease of Escherichia coli has been replaced with hydrophobic (Ala, Val, Ile, Phe), hydrophilic (Ser, Thr), or charged (Asp, Lys) residues, and the properties of the replacement mutants have been analyzed. Although Cys 148 is not essential for transport, the size and polarity of the side chain at this position modifies transport activity and substrate specificity. Thus, small hydrophobic side chains (Ala, Val) generally increase the apparent affinity of the permease for substrate, while hydrophilic side chains (Ser, Thr, Asp) decrease apparent affinity and bulky or positively charged side chains (Phe, Lys) virtually abolish activity. In addition, hydrophilic substitutions (Ser, Thr, Asp) alter the specificity of the permease toward monosaccharides relative to disaccharides. On the basis of these and other observations, it is concluded that Cys 148 is located in a sugar binding site of lac permease and probably interacts hydrophobically with the galactosyl moiety. The postulate receives more direct support from site-directed fluorescence labeling studies presented in the following paper in this issue [Wu, J., & Kaback, H. R. (1994) Biochemistry (following paper in this issue)].
Lactose transport in membrane vesicles containing lactose permease with a single Cys residue in place of Val 315 is inactivated by N-ethylmaleimide in a manner that is stimulated by substrate or by a H+ electrochemical gradient (delta microH+; Sahin-Tóth M, Kaback HR, 1993, Protein Sci 2:1024-1033). The findings are confirmed and extended in this communication. Purified, reconstituted Val 315-->Cys permease reacts with N-ethylmaleimide or hydrophobic fluorescent maleimides but not with a membrane impermeant thiol reagent, and beta-galactosides specifically stimulate the rate of labeling. Furthermore, the reactivity of purified Val 315-->Cys permease is enhanced by imposition of a membrane potential (delta psi, interior negative). The results indicate that either ligand binding or delta psi induces a conformational change in the permease that brings the N-terminus of helix X into an environment that is more accessible from the lipid phase.
The gene coding for the lactose carrier of Citrobacter freundii was cloned into the plasmid pBR322. The gene was sequenced and the amino acid sequence was found to be 70% identical to the lactose carrier of E. coli. All of the charged residues in the membrane spanning region were conserved. The sugar specificity is somewhat different from that of E. coli. The C. freundii carrier has less activity for lactose and more activity for o-nitrophenylgalactose (ONPG) than the carrier of E. coli. (C) 1994 Academic Press. Inc.
Using a functional lactose permease mutant devoid of Cys residues (C-less permease), each amino acid residue in putative transmembrane helix VII and the flanking cytoplasmic and periplasmic regions (from Leu212 to Glu255) was replaced individually with Cys. Of the 44 single-Cys mutants, 40 exhibit high transport activity, accumulating lactose to > 50% of the steady-state observed with C-less permease. In contrast, permease with Cys in place of Ala213 or Tyr236 exhibits low but significant activity, and Cys substitution for Asp237 or Asp240 yields permease molecules with little or no activity due to disruption of charge-neutralizing interactions between Asp237 and Lys358 or Asp240 and Lys319, respectively. Immunological analysis reveals that membrane levels of the mutant proteins are comparable to that of C-less permease with the exception of Tyr228-->Cys, which exhibits reduced but significant levels of permease. Finally, the effect of N-ethylmaleimide (NEM) was tested on each mutant, and the results indicate that the transport activity of the great majority of the mutants is not affected by the alkylating agent. Remarkably, the six positions where Cys replacements render the permease highly sensitive to inactivation by NEM are confined to the C-terminal half of helix VII, a region that is strongly conserved among transport proteins homologous to lactose permease. The results demonstrate that although no residue per se in the region scanned is essential, structural features of the C terminus of helix VII may be important for transport activity.
Recently we described the use of site-directed pyrene labeling of engineered lactose permease containing paired Cys residues to obtain proximity relationships between helices in the C-terminal half of the molecule [Jung, K., Jung, H., Wu, J., Privé, G. G., & Kaback, H.R. (1993) Biochemistry 32, 12273]. Pyrene excimer fluorescence was detected for the double Cys mutants His322-->Cys/Glu325-->Cys, Arg302-->Cys/Glu325-->Cys, and Glu269-->Cys/His322-->Cys, indicating that helix X (His322-->Cys/Glu325-->Cys) is in an alpha-helical conformation and that helices VIII (Glu269-->Cys) and IX (Arg302-->Cys) are close to helix X (His322-->Cys and Glu325-->Cys). In this report, these interactions are used to study dynamic aspects of the permease. Excimer fluorescence between helices VIII and X or helices IX and X is markedly diminished by sodium dodecyl sulfate, while the excimer observed within helix X is unaffected, suggesting that tertiary interactions are disrupted by the denaturant with little effect on secondary structure. Furthermore, excimer fluorescence observed between helices VIII (Glu269-->Cys) and helix X (His322-->Cys) is quenched by Tl+, and the effect is markedly and specifically attenuated by ligands of the permease, suggesting that the pyrene becomes less accessible to the aqueous phase. The reactivity of single Cys residues at positions 269 or 322 was also examined by studying the rate of increase in fluorescence with N-(l-pyrenyl)maleimide. With both mutants, ligands of the permease cause a dramatic increase in reactivity which is consistent with the notion that these positions are transferred into a more hydrophobic environment.(ABSTRACT TRUNCATED AT 250 WORDS)
The lactose permease of Escherichia coli is a paradigm for polytopic membrane transport proteins that transduce free energy stored in an electrochemical ion gradient into work in the form of a concentration gradient. Although the permease consists of 12 hydrophobic transmembrane domains in probable alpha-helical conformation that traverse the membrane in zigzag fashion connected by hydrophilic "loops", little information is available regarding the folded tertiary structure of the molecule. In this paper, we describe an approach to studying proximity relationships in lactose permease that is based upon site-directed pyrene labeling of combinations of paired Cys replacements in a mutant devoid of Cys residues. Since pyrene exhibits excimer fluorescence if two molecules are within about 3.5 A, the proximity between paired labeled residues can be determined. The results demonstrate that putative helices VIII and IX are close to helix X. Taken together with other findings indicating that helix VII is close to helices X and XI, the data lead to a model that describes the packing of helices VII-XI.
Using a functional lactose permease mutant devoid of Cys residues (C-less permease), each amino acid in putative transmembrane helix XI was individually replaced with Cys (from Ala347 to Ser366). Fifteen of the 20 mutants are highly functional and accumulate lactose to > 60% of the level achieved by C-less permease, and an additional three mutants, all located at the cytoplasmic end of the helix, exhibit lower but significant lactose accumulation. Cys replacements for Thr348 or Lys358 result in virtually inactive permease. Lys358, however, is not essential for active lactose transport but plays a role in permease folding or membrane insertion by interacting with Asp237. Immunoblots reveal that all mutant proteins are present in the membrane in amounts comparable to C-less with the exception of Lys358-->Cys which is hardly detectable, as expected. The results highlight Thr348 as a potentially important residue for further analysis. Finally, all active mutants were assayed after treatment with the sulfhydryl reagent N-ethyl-maleimide, and results range from nearly complete inhibition to almost 2-fold stimulation. Remarkably, all of the strongly inhibited positions lie on one face of helix XI. The implications of the findings for packing of transmembrane helices in the C-terminal half of the permease are discussed.