Preparation, characterization, and properties of monoclonal antibodies against the lac carrier protein from Escherichia coli

Monoclonal antibody 4B1 influences the pKa of Glu325 in lactose permease (LacY) from Escherichia coli: evidence from SEIRAS

The monoclonal antibody 4B1 binds to a conformational epitope on the periplasmic side of lactose permease (LacY) of Escherichia coli and inhibits H⁺ /lactose symport and lactose efflux under nonenergized conditions. At the same time, ligand binding and translocation reactions that do not involve net H⁺ translocation remain unaffected by 4B1. In this study, surface-enhanced infrared absorption spectroscopy applied to the immobilized LacY was used to study the pH-dependent changes in LacY and to access in situ the effect of the 4B1 antibody on the pK_a of Glu325, the primary functional H⁺ -binding site in LacY. A small shift of the pK value from 10.5 to 9.5 was identified that can be corroborated with the inactivation of LacY upon 4B1 binding.

Mentors: Ron Kaback

Carrasco reflects on her postdoctoral advisor, Ron Kaback—an exceptional scientist and inspiring mentor.

Label-Free Monitoring of Human IgG/Anti-IgG Recognition Using Bloch Surface Waves on 1D Photonic Crystals

Optical biosensors based on one-dimensional photonic crystals sustaining Bloch surface waves are proposed to study antibody interactions and perform affinity studies. The presented approach utilizes two types of different antibodies anchored at the sensitive area of a photonic crystal-based biosensor. Such a strategy allows for creating two or more on-chip regions with different biochemical features as well as studying the binding kinetics of biomolecules in real time. In particular, the proposed detection system shows an estimated limit of detection for the target antibody (anti-human IgG) smaller than 0.19 nM (28 ng/mL), corresponding to a minimum surface mass coverage of 10.3 ng/cm². Moreover, from the binding curves we successfully derived the equilibrium association and dissociation constants (K_A = 7.5 × 10⁷ M^-1; K_D = 13.26 nM) of the human IgG⁻anti-human IgG interaction.

Lateral diffusion of membrane proteins

We measured the lateral mobility of integral membrane proteins reconstituted in giant unilamellar vesicles (GUVs), using fluorescence correlation spectroscopy. Receptor, channel, and transporter proteins with 1-36 transmembrane segments (lateral radii ranging from 0.5 to 4 nm) and a alpha-helical peptide (radius of 0.5 nm) were fluorescently labeled and incorporated into GUVs. At low protein-to-lipid ratios (i.e., 10-100 proteins per microm(2) of membrane surface), the diffusion coefficient D displayed a weak dependence on the hydrodynamic radius (R) of the proteins [D scaled with ln(1/R)], consistent with the Saffman-Delbruck model. At higher protein-to lipid ratios (up to 3000 microm(-2)), the lateral diffusion coefficient of the molecules decreased linearly with increasing the protein concentration in the membrane. The implications of our findings for protein mobility in biological membranes (protein crowding of approximately 25,000 microm(-2)) and use of diffusion measurements for protein geometry (size, oligomerization) determinations are discussed.

Lessons from lactose permease

An X-ray structure of the lactose permease of Escherichia coli (LacY) in an inward-facing conformation has been solved. LacY contains N- and C-terminal domains, each with six transmembrane helices, positioned pseudosymmetrically. Ligand is bound at the apex of a hydrophilic cavity in the approximate middle of the molecule. Residues involved in substrate binding and H+ translocation are aligned parallel to the membrane at the same level and may be exposed to a water-filled cavity in both the inward- and outward-facing conformations, thereby allowing both sugar and H+ release directly into either cavity. These structural features may explain why LacY catalyzes galactoside/H+ symport in both directions utilizing the same residues. A working model for the mechanism is presented that involves alternating access of both the sugar- and H+-binding sites to either side of the membrane.

Role of YidC in folding of polytopic membrane proteins

YidC of Echerichia coli, a member of the conserved Alb3/Oxa1/YidC family, is postulated to be important for biogenesis of membrane proteins. Here, we use as a model the lactose permease (LacY), a membrane transport protein with a known three-dimensional structure, to determine whether YidC plays a role in polytopic membrane protein insertion and/or folding. Experiments in vivo and with an in vitro transcription/translation/insertion system demonstrate that YidC is not necessary for insertion per se, but plays an important role in folding of LacY. By using the in vitro system and two monoclonal antibodies directed against conformational epitopes, LacY is shown to bind the antibodies poorly in YidC-depleted membranes. Moreover, LacY also folds improperly in proteoliposomes prepared without YidC. However, when the proteoliposomes are supplemented with purified YidC, LacY folds correctly. The results indicate that YidC plays a primary role in folding of LacY into its final tertiary conformation via an interaction that likely occurs transiently during insertion into the lipid phase of the membrane.

Intermolecular thiol cross-linking via loops in the lactose permease of Escherichia coli

Previous experiments using intermolecular thiol cross-linking to determine surface-exposed positions in the transmembrane helices of the lactose permease suggest that only positions accessible from the aqueous phase are susceptible to cross-linking. This approach is now extended to most of the remaining positions in the molecule. Of an additional 143 single-Cys mutants studied, homodimer formation is observed with both a 5-A- and a 21-A-long crosslinking agent containing bis-methane thiosulfonate reactive groups in 33 mutants and exclusively with the 21-A-long reagent in 43 mutants. Furthermore, intermolecular cross-linking has little or no effect on transport activity, thereby providing further support for the argument that lactose permease is functionally, as well as structurally, a monomer in the membrane. In addition, evidence is presented indicating that reentrance loops are unlikely in this polytopic membrane transport protein.

In vitro synthesis of lactose permease to probe the mechanism of membrane insertion and folding

Insertion and folding of polytopic membrane proteins is an important unsolved biological problem. To study this issue, lactose permease, a membrane transport protein from Escherichia coli, is transcribed, translated, and inserted into inside-out membrane vesicles in vitro. The protein is in a native conformation as judged by sensitivity to protease, binding of a monoclonal antibody directed against a conformational epitope, and importantly, by functional assays. By exploiting this system it is possible to express the N-terminal six helices of the permease (N(6)) and probe changes in conformation during insertion into the membrane. Specifically, when N(6) remains attached to the ribosome it is readily extracted from the membrane with urea, whereas after release from the ribosome or translation of additional helices, those polypeptides are not urea extractable. Furthermore, the accessibility of an engineered Factor Xa site to Xa protease is reduced significantly when N(6) is released from the ribosome or more helices are translated. Finally, spontaneous disulfide formation between Cys residues at positions 126 (Helix IV) and 144 (Helix V) is observed when N(6) is released from the ribosome and inserted into the membrane. Moreover, in contrast to full-length permease, N(6) is degraded by FtsH protease in vivo, and N(6) with a single Cys residue at position 148 does not react with N-ethylmaleimide. Taken together, the findings indicate that N(6) remains in a hydrophilic environment until it is released from the ribosome or additional helices are translated and continues to fold into a quasi-native conformation after insertion into the bilayer. Furthermore, there is synergism between N(6) and the C-terminal half of permease during assembly, as opposed to assembly of the two halves as independent domains.

Helices VII and X in the lactose permease of Escherichia coli: proximity and ligand-induced distance changes

By using functional lactose permease devoid of native Cys residues with a discontinuity in the periplasmic loop between helices VII and VIII (N(7)/C(5) split permease), cross-linking between engineered paired Cys residues in helices VII and X was studied with the homobifunctional, thiol-specific cross-linkers 1,1-methanediyl bismethanethiosulfonate (3 A), N,N'-o- phenylenedimaleimide (6 A) and N,N'-p-phenylenedimaleimide (10 A). Mutant Asp240-->Cys (helix VII)/Lys319-->Cys (helix X) cross-links most efficiently with the 3 A reagent, providing direct support for studies indicating that Asp240 and Lys319 are in close proximity and charge paired. Furthermore, cross-linking the two positions inactivates the protein. Other Cys residues more disposed towards the middle of helix VII cross-link to Cys residues in the approximate middle of helix X, while no cross-linking is evident with paired Cys residues at the periplasmic or cytoplasmic ends of these helices. Thus, helices VII and X are in close proximity in the middle of the membrane. In the presence of ligand, the distance between Cys residues at positions 240 (helice VII) and 319 (helix X) increases. In contrast, the distance between paired Cys residues more disposed towards the cytoplasmic face of the membrane decreases in a manner suggesting that ligand binding induces a scissors-like movement between the two helices. The results are consistent with a recently proposed mechanism for lactose/H(+) symport in which substrate binding induces a conformational change between helices VII and X, during transfer of H(+) from His322 (helix X)/Glu269 (helix VIII) to Glu325 (helix X).

A revised model for the structure and function of the lactose permease. Evidence that a face on transmembrane segment 2 is important for conformational changes

The lactose permease is an integral membrane protein that cotransports H(+) and lactose into the bacterial cytoplasm. Previous work has shown that bulky substitutions at glycine 64, which is found on the cytoplasmic edge of transmembrane segment 2 (TMS-2), cause a substantial decrease in the maximal velocity of lactose uptake without significantly affecting the K(m) values (Jessen-Marshall, A. E., Parker, N. J., and Brooker, R. J. (1997) J. Bacteriol. 179, 2616-2622). In the current study, mutagenesis was conducted along the face of TMS-2 that contains glycine-64. Single amino acid substitutions that substantially changed side-chain volume at codons 52, 57, 59, 63, and 66 had little or no effect on transport activity, whereas substitutions at codons 49, 53, 56, and 60 were markedly defective and/or had lower levels of expression. According to helical wheel plots, Phe-49, Ser-53, Ser-56, Gln-60, and Gly-64 form a continuous stripe along one face of TMS-2. Several of the TMS-2 mutants (S56Y, S56L, S56Q, Q60A, and Q60V) were used as parental strains to isolate mutants that restore transport activity. These mutations were either first-site mutations or second-site suppressors in TMS-1, TMS-2, TMS-7 or TMS-11. A kinetic analysis showed that the suppressors had a higher rate of lactose transport compared with the corresponding parental strains. Overall, the results of this study are consistent with the notion that a face on TMS-2, containing Phe-49, Ser-53, Ser-56, Gln-60, and Gly-64, plays a critical role in conformational changes associated with lactose transport. We hypothesize that TMS-2 slides across TMS-7 and TMS-11 when the lactose permease interconverts between the C1 and C2 conformations. This idea is discussed within the context of a revised model for the structure of the lactose permease.

Proximity relationships between helices I and XI or XII in the lactose permease of Escherichia coli determined by site-directed thiol cross-linking

The lactose permease of Escherichia coli was expressed in two fragments (split permease), each with a Cys residue, and cross-linking was studied. Split permease with a discontinuity in either loop II/III (N2C10permease) or loop VI/VII (N6C6permease) was used. Proximity of multiple pairs of Cys residues in helices I and XI or XII was examined by using three homobifunctional thiol-specific cross-linking reagents of different lengths and flexibilities (6 A, rigid; 10 A, rigid; 16 A, flexible) or iodine. Cys residues in the periplasmic half of helix I cross-link to Cys residues in the periplasmic half of helix XI. In contrast, no cross-linking is evident with paired Cys residues near the cytoplasmic ends of helices I and XI. Therefore, the periplasmic halves of helices I and XI are in close proximity, and the helices tilt away from each other towards the cytoplasmic face of the membrane. Cross-linking is also found with paired Cys residues near the middle of helices I and XII, but not with paired Cys residues near either end of the helices. Thus, helices I and XII are in close proximity only in the approximate middle of the membrane. Based on the findings, a modified helix packing model is proposed.

Production and characterization of monoclonal antibodies directed against native epitopes of NhaA, the Na+/H+ antiporter of Escherichia coli

Monoclonal antibodies (mAbs) recognizing native epitopes are an important tool for functional and structural studies of proteins, yet they have rarely been used with transport proteins. In an attempt to raise monoclonal antibodies against the NhaA Na+/H+ antiporter of Escherichia coli we encountered difficulties in the screening procedure, which is based on the standard enzyme-linked immunosorbent assay (ELISA). Here we report a rapid and efficient method of screening for anti-NhaA mAbs which recognize native epitopes of the antiporter. The method is based on the use of His-tagged protein, Ni2+-nitrilotriacetic acid coated plates and non-denaturing conditions in the assay. With this procedure four mAbs were obtained, three of which recognize the NhaA in its native conformation and one preferentially recognizes the denatured form. The latter mAb is Western blot positive, the others are Western blot negative and bind the detergent solubilized NhaA as assayed by gel filtration chromatography. Competition experiments show that the native epitopes are common to both the His-tagged and the wild-type protein. We suggest that in the standard ELISA the NhaA protein is not presented to the antibody in the native conformation whereas the His tag based protocol favors this presentation. Indeed, we could remarkably improve the low reactivity of the standard ELISA by coating the plates with anti-NhaA mAb and use it to present NhaA ('sandwich' ELISA or two antibodies assay). Remarkably, two of the mAbs (5H4, 2C5) which bind native NhaA inhibit drastically the deltapH driven 22Na uptake mediated by His-tagged NhaA reconstituted in proteoliposomes. Hence, these mAbs afford a new tool to study the structure/function relationship of the antiporter.

Phospholipid-assisted protein folding: phosphatidylethanolamine is required at a late step of the conformational maturation of the polytopic membrane protein lactose permease

Previously we presented evidence that phosphatidylethanolamine (PE) acts as a molecular chaperone in the folding of the polytopic membrane protein lactose permease (LacY) of Escherichia coli. Here we provide more definitive evidence supporting the chaperone properties of PE. Membrane insertion of LacY prevents its irreversible aggregation, and PE participates in a late step of conformational maturation. The temporal requirement for PE was demonstrated in vitro using a coupled translation-membrane insertion assay that allowed the separation of membrane insertion from phospholipid-assisted folding. LacY was folded properly, as assessed by recognition with conformation-specific monoclonal antibodies, when synthesized in the presence of PE-containing inside-out membrane vesicles (IOVs) or in the presence of IOVs initially lacking PE but supplemented with PE synthesized in vitro either co- or post-translationally. The presence of IOVs lacking PE and containing anionic phospholipids or no addition of IOVs resulted in misfolded or aggregated LacY, respectively. Therefore, critical folding steps occur after membrane insertion dependent on the interaction of LacY with PE to prevent illicit interactions which lead to misfolding of LacY.

An analysis of suppressor mutations suggests that the two halves of the lactose permease function in a symmetrical manner

A conserved motif, GXXX(D/E)(R/K)XG[X](R/K)(R/K), is located in loop 2/3 and loop 8/9 in the lactose permease, and also in hundreds of evolutionarily related transporters. The importance of conserved residues in loop 8/9 was previously investigated (Pazdernik, N. J., Jessen-Marshall, A. E., and Brooker, R. J. (1997) J. Bacteriol. 179, 735-741). Although this loop was tolerant of many substitutions, a few mutations in the first position of the motif were shown to dramatically decrease lactose transport. In the current study, a mutant at the first position in the motif having very low lactose transport, Leu280, was used as a parental strain to isolate second-site revertants that restore function. A total of 23 independent mutants were sequenced and found to have a second amino acid substitution at several locations (G46C, G46S, F49L, A50T, L212Q, L216Q, S233P, C333G, F354C, G370C, G370S, and G370V). A kinetic analysis revealed that the first-site mutation, Leu280, had a slightly better affinity for lactose compared with the wild-type strain, but its Vmax for lactose transport was over 30-fold lower. The primary effect of the second-site mutations was to increase the Vmax for lactose transport, in some cases, to levels that were near the wild-type value. When comparing this study to second-site mutations obtained from loop 2/3 defective strains, a striking observation was made. Mutations in three regions of the protein, codons 45-50, 234-241, and 366-370, were able to restore functionality to both loop 2/3 and loop 8/9 defects. These results are discussed within the context of a C1/C2 alternating conformation model in which lactose translocation occurs by a conformational change at the interface between the two halves of the protein.

Helix packing in polytopic membrane proteins: the lactose permease of Escherichia coli

Recent advances in protein engineering have facilitated the development of alternative approaches to determine helix packing in polytopic membrane proteins. Using the lac permease as a paradigm, several site-directed biophysical and biochemical techniques are described which should be generally applicable.

Helix proximity and ligand-induced conformational changes in the lactose permease of Escherichia coli determined by site-directed chemical crosslinking

N and C-terminal halves of lactose permease, each with a single-Cys residue, were co-expressed, and crosslinking was studied. Iodine or N,N'-o-phenylenedimaleimide (o-PDM; rigid 6 A), crosslinks Asn245 Cys (helix VII) and Ile52 --> Cys or Ser53 --> Cys (helix II). N,N'-p-phenylenedimaleimide (p-PDM; rigid 10 A) crosslinks the 245/53 Cys pair weakly, but does not crosslink 245/52, and 1,6-bis-maleimidohexane (BMH; flexible 16 A) crosslinks both pairs less effectively than o-PDM. Thus, 245 is almost equidistant from 52 and 53 by up to about 6 A. BMH or p-PDM crosslinks Gln242 --> Cys and Ser53 --> Cys, but o-PDM is ineffective, indicating that distance varies by up to 10 A. Ligand binding increases crosslinking of 245/53 with p-PDM or BMH, has little effect with o-PDM and decreases iodine crosslinking. Similar effects are observed with 245/52. Ligand increases 242/53 crosslinking with p-PDM or BMH, but no crosslinking is observed with o-PDM. Therefore, ligand induces a translational or scissors-like displacement of the helices by 3-4 A. Crosslinking 245/53 inhibits transport indicating that conformational flexibility is important for function.

A phospholipid acts as a chaperone in assembly of a membrane transport protein

A mutant of Escherichia coli lacking phosphatidylethanolamine (PE) and a monoclonal antibody (mAb 4B1) directed against a conformationally sensitive epitope (4B1) of lactose permease were used to establish a novel role for a phospholipid in the assembly of a membrane protein. Epitope 4B1 is readily detectable in spheroplasts and right-side-out membrane vesicles from PE-containing but not from PE-deficient cells expressing lactose permease. Lactose permease from PE-containing membranes, but not from PE-deficient membranes, subjected to sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis and Western blot analysis is also recognized by mAb 4B1. If total E. coli phospholipids or PE (but not phosphatidylcholine, phosphatidylglycerol, or cardiolipin) are blotted on nitrocellulose sheets (Eastern blot) prior to transfer of proteins from SDS-polyacrylamide gels, the permease from PE-deficient cells regains its recognition by mAb 4B1. Therefore, PE is required during assembly to form epitope 4B1, but, once formed, sufficient "conformational memory" is retained in the permease to either retain or reform this epitope in the absence of PE. Lactose permease lacking epitope 4B1 can be induced to form the epitope if partially denatured and then renatured in the presence of PE specifically. These results establish for the first time a role for PE as a molecular chaperone in the assembly of the lactose permease.

Fluorescence of native single-Trp mutants in the lactose permease from Escherichia coli: structural properties and evidence for a substrate-induced conformational change

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 beta,D-galactopyranosyl 1-thio-beta,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 microM. 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.

Cysteine scanning mutagenesis of helix V in the lactose permease of Escherichia coli

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.

Insertion of the polytopic membrane protein lactose permease occurs by multiple mechanisms

The lactose permease of Escherichia coli has 12 transmembrane hydrophobic domains in probable alpha-helical conformation connected by hydrophilic loops. Previous studies [Consler, T. G., Persson, B., et al. (1993) Proc. Natl. Acad. Sci. U.S.A. 90, 6934-6938] demonstrate that a peptide fragment (the XB domain) containing a factor Xa protease site immediately upstream of a biotin acceptor domain can be engineered into the permease, thereby allowing rapid purification to a high state of purity. Here we describe the use of the XB domain to probe topology and insertion. Cells expressing permease with the XB domain at the N terminus, at the C terminus, or in loop 6 or 10 on the cytoplasmic face of the membrane catalyze active transport, although only the chimeras with the XB domain at the C terminus or in loop 6 are biotinylated. In contrast, chimeras with the XB domain in periplasmic loop 3 or 7 are inactive, but strikingly, both constructs are biotinylated. Furthermore, the XB domain in all the constructs, particularly in the loop 3 and loop 7 chimeras, is accessible from the cytoplasmic face of the membrane, as evidenced by factor Xa proteolysis or avidin binding studies with spheroplasts and disrupted membrane preparations. Finally, alkaline phosphatase fusions one loop downstream from each periplasmic XB domain exhibit high phosphatase activity. Thus, the presence of the XB domain in a periplasmic loop apparently blocks translocation of a discrete segment of the permease consisting of the loop and the two adjoining helices without altering insertion of the remainder of the protein.(ABSTRACT TRUNCATED AT 250 WORDS)

The role of transmembrane domain III in the lactose permease of Escherichia coli

Deletion of putative transmembrane helix III from the lactose permease of Escherichia coli results in complete loss of transport activity. Similarly, replacement of this region en bloc with 23 contiguous Ala, Leu, or Phe residues abolishes active lactose transport. The observations suggest that helix III may contain functionally important residues; therefore, this region was subjected to Cys-scanning mutagenesis. Using a functional mutant devoid of Cys residues (C-less permease) each residue from Tyr 75 to Leu 99 was individually replaced with Cys. Twenty-one of the 25 mutants accumulate lactose to > 70% of the steady-state exhibited by C-less permease, and an additional 3 mutants transport to lower, but significant levels (40-60% of C-less). Cys replacement for Leu 76 results in low transport activity (18% of C-less). However, when placed in the wild-type background, mutant Leu 76-->Cys exhibits highly significant rates of transport (55% of wild type) and steady-state levels of lactose accumulation (65% of wild type). Immunoblots reveal that the mutants are inserted into the membrane at concentrations comparable to wild type. Studies with N-ethylmaleimide show that mutant Gly 96-->Cys is rapidly inactivated, whereas the other single-Cys mutants are not altered significantly by the alkylating agent. Moreover, the rate of inactivation of Gly 96-->Cys permease is enhanced at least 2-fold in the presence of beta-galactopyranosyl 1-thio-beta, D-galactopyranoside. The observations demonstrate that although no residue per se appears to be essential, structural properties of helix III are important for active lactose transport.

Cysteine-scanning mutagenesis of putative helix VII in the lactose permease of Escherichia coli

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.

Properties of permease dimer, a fusion protein containing two lactose permease molecules from Escherichia coli

An engineered fusion protein containing two tandem lactose permease molecules (permease dimer) exhibits high transport activity and is used to test the phenomenon of negative dominance. Introduction of the mutation Glu-325-->Cys into either the first or the second half of the dimer results in a 50% decrease in activity, whereas introduction of the mutation into both halves of the dimer abolishes transport. Lactose transport by permease dimer is completely inactivated by N-ethylmaleimide; however, 40-45% activity is retained after N-ethylmaleimide treatment when either the first or the second half of the dimer is replaced with a mutant devoid of cysteine residues. The observations demonstrate that both halves of the fusion protein are equally active and suggest that each half may function independently. To test the possibility that oligomerization between dimers might account for the findings, a permease dimer was constructed that contains two different deletion mutants that complement functionally when expressed as untethered molecules. Because this construct does not catalyze lactose transport to any extent whatsoever, it is unlikely that the two halves of the dimer interact or that there is an oligomeric interaction between dimers. The approach is consistent with the contention that the functional unit of lactose permease is a monomer.

Cysteine scanning mutagenesis of the N-terminal 32 amino acid residues in the lactose permease of Escherichia coli

Using a functional lactose permease mutant devoid of Cys residues (C-less permease), each amino acid residue in the hydrophilic N-terminus and the first putative transmembrane helix was systematically replaced with Cys (from Tyr-2 to Trp-33). Twenty-three of 32 mutants exhibit high lactose accumulation (70-100% or more of C-less), and an additional 8 mutants accumulate to lower but highly significant levels. Surprisingly, Cys replacement for Gly-24 or Tyr-26 yields fully active permease molecules, and permease with Cys in place of Pro-28 also exhibits significant transport activity, although previous mutagenesis studies on these residues suggested that they may be required for lactose transport. As expected, Cys replacement for Pro-31 completely inactivates, in agreement with previous findings indicating that "helix-breaking" propensity at this position is necessary for full activity (Consler TG, Tsolas O, Kaback HR, 1991, Biochemistry 30:1291-1297). Twenty-nine mutants are present in the membrane in amounts comparable to C-less permease, whereas membrane levels of mutants Tyr-3-->Cys and Phe-12-->Cys are slightly reduced, as judged by immunological techniques. Dramatically, mutant Phe-9-->Cys is hardly detectable when expressed from the lac promoter/operator at a relatively low rate, but is present in the membrane in a stable form when expressed at a high rate from the T7 promoter. Finally, studies with N-ethylmalemide show that 6 Cys-replacement mutants that cluster at the C-terminal end of putative helix I are inactivated significantly.(ABSTRACT TRUNCATED AT 250 WORDS)

Role of glutamate-269 in the lactose permease of Escherichia coli

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.

What's new with lactose permease

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 a recent approach site-directed fluorescence labeling is being used to study proximity relationships in lactose permease. The experiments are 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 3.5A, 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 to XI.

Properties of interacting aspartic acid and lysine residues in the lactose permease of Escherichia coli

The side chains of the interacting pair Asp237(helix VII)-Lys358(helix XI) or Asp240(helix VII)-Lys319(helix X) in the lactose permease of Escherichia coli were extended by replacement with Glu and/or Arg or by site-specific derivatization of single-Cys replacement mutants. Iodoacetic acid was used to carboxymethylate Cys, or methanethiosulfonate derivatives [Akabas, M. H., Stauffer, D. A., Xu, M., & Karlin, A. (1992) Science 258, 307] were used to attach negatively charged ethylsulfonate or positively charged ethylammonium groups. Replacement of Asp237 with Glu, carboxymethyl-Cys, or sulfonylethylthio-Cys yields active permease with Lys or Arg at position 358. Similarly, the permease tolerates replacement of Lys358 with Arg or ammonioethylthio-Cys with Asp or Glu at position 237. Remarkably, moreover, permease with Lys, Arg, or ammonioethylthio-Cys in place of Asp237 is highly active when Lys358 is replaced with Asp or Glu, in agreement with the conclusion that the polarity of the charge interaction can be reversed without loss of activity [Sahin-Tóth, M., Dunten, R. L., Gonzalez, A., & Kaback, H. R. (1992) Proc. Natl. Acad. Sci. U.S.A. 89, 10547]. In contrast, replacement of Asp240 with Glu abolishes lactose transport, and permease with carboxymethyl-Cys, at position 240 is inactive when paired with Lys319, but it exhibits significant activity with Arg319. Interestingly, sulfonylethylthio-Cys substitution for Asp240 also results in significant transport activity. Permease with Arg or ammonioethylthio-Cys in place of Lys319 exhibits high activity with Asp240 as the negative counterion, but no lactose transport is observed when either of these modifications is paired with Glu240.(ABSTRACT TRUNCATED AT 250 WORDS)

Immunological Evidence for the Existence of a Carrier Protein for Sucrose Transport in Tonoplast Vesicles from Red Beet (Beta vulgaris L.) Root Storage Tissue

Monoclonal antibodies were raised in mice against a highly purified tonoplast fraction from isolated red beet (Beta vulgaris L. ssp. conditiva) root vacuoles. Positive hybridoma clones and sub-clones were identified by prescreening using an enzyme-linked immunosorbent assay (ELISA) and by postscreening using a functional assay. This functional assay consisted of testing the impact of hybridoma supernatants and antibody-containing ascites fluids on basal and ATP-stimulated sugar uptake in vacuoles, isolated from protoplasts, as well as in tonoplast vesicles, prepared from tissue homogenates of red beet roots. Antibodies from four clones were particularly positive in ELISAs and they inhibited sucrose uptake significantly. These antibodies were specific inhibitors of sucrose transport, but they exhibited relatively low membrane and species specificity since uptake into red beet root protoplasts and sugarcane tonoplast vesicles was inhibited as well. Fast protein liquid chromatography assisted size exclusion chromatography on Superose 6 columns yielded two major peaks in the 55 to 65-kD regions and in the 110- to 130-kD regions of solubilized proteins from red beet root tonoplasts, which reacted positively in immunoglobulin-M(IgM)-specific ELISAs with anti-sugarcane tonoplast monoclonal IgM antibodies. Only reconstituted proteoliposomes containing polypeptides from the 55- to 65-kD band took up [14C]-sucrose with linear rates for 2 min, suggesting that this fraction contains the tonoplast sucrose carrier.

Cysteine scanning mutagenesis of putative transmembrane helices IX and X in the lactose permease of Escherichia coli

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 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 beta-galactopyranosyl 1-thio-beta-D-galactopyranoside (TDG) or an H+ electrochemical gradient (delta mu-H+). 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 delta mu-H+ probably reflects a conformational alteration induced by either substrate binding or delta mu-H+.

Role of the charge pair aspartic acid-237-lysine-358 in the lactose permease of Escherichia coli

Using a lactose permease mutant devoid of Cys residues (C-less permease), Asp237 and Lys358 were replaced with Cys or other amino acids to pursue the proposal that the two residues form a charge pair [King, S. C., Hansen, C. L., & Wilson, T.H. (1991) Biochim. Biophys. Acta 1062, 177-186]. Individual replacement of Asp237 with Cys, Ala, or Lys or replacement of Lys358 with Cys, Ala, or Asp virtually abolishes active lactose transport. However, simultaneous replacement of both residues with Cys and/or Ala yields permease with high activity. Therefore, neutral amino acid substitutions at either position are detrimental only because they leave the opposing charge unpaired. Strikingly, moreover, when Asp237 is interchanged with Lys358, high activity is observed. The results indicate strongly that Asp237 and Lys358 interact to form a salt bridge and that neither residue nor the salt bridge per se is important for activity. Immunoblots reveal low membrane levels of the active mutants lacking the putative salt bridge, suggesting a role for the salt bridge in either permease folding or stability and raising the possibility that the salt bridge may exist in a folding intermediate but not in the mature protein. Remarkably, however, a mutant with Cys in place of Asp237 is restored to full activity by carboxymethylation which recreates a negative charge at position 237. Pulse-chase analysis and heat-inactivation studies indicate that the stability of the double mutant with Cys at positions 237 and 358 is comparable to C-less. Therefore, the interaction between Asp237 and Lys358 is likely to be important for permease folding and is maintained in the mature protein.(ABSTRACT TRUNCATED AT 250 WORDS)

Insertional mutagenesis of hydrophilic domains in the lactose permease of Escherichia coli

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.

Functional interactions between putative intramembrane charged residues in the lactose permease of Escherichia coli

Using a lactose permease mutant devoid of Cys residue ("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. & 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 a 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 Asp-237 and Lys-358, interchanging Asp-240 and Lys-319 abolishes active 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.

Amino acid substitution in the lactose carrier protein with the use of amber suppressors

Five lacY mutants with amber stop codons at known positions were each placed into 12 different suppressor strains. The 60 amino acid substitutions obtained in this manner were tested for growth on lactose-minimal medium plates and for transport of lactose, melibiose, and thiomethylgalactoside. Most of the amino acid substitutions in the regions of the putative loops (between transmembrane alpha helices) resulted in a reasonable growth rate on lactose with moderate-to-good transport activity. In one strain (glycine substituted for Trp-10), abnormal sugar recognition was found. The substitution of proline for Trp-33 (in the region of the first alpha helix) showed no activity, while four additional substitutions (lysine, leucine, cysteine, and glutamic acid) showed low activity. Altered sugar specificity was observed when Trp-33 was replaced by serine, glutamine, tyrosine, alanine, histidine, or phenylalanine. It is concluded that Trp-33 may be involved directly or indirectly in sugar recognition.

The N-terminal 22 amino acid residues in the lactose permease of Escherichia coli are not obligatory for membrane insertion or transport 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.

Functional complementation of internal deletion mutants in the lactose permease of Escherichia coli

Using the lactose permease of Escherichia coli, a well-characterized membrane protein with 12 transmembrane domains, we demonstrated that certain paired in-frame deletion constructs complement each other functionally. Although cells expressing the deletion mutants individually are unable to catalyze active lactose accumulation, cells simultaneously expressing specific pairs of deletions catalyze transport up to 60% as do cells expressing wild-type permease. Moreover, complementation clearly does not occur at the level of DNA but probably occurs at the protein level. Remarkably, functional complementation is observed only with pairs of permease molecules containing large deletions and is not observed with missense mutations or point deletions. Although the mechanism of functional complementation is obscure, the findings indicate that certain pairs of permease molecules containing specific internal deletions can interact to form a functional complex in the same way phenomenologically as do independently expressed polypeptides corresponding to different N- and C-terminal portions of the permease.

Selective Inhibition of Active Uptake of Sucrose into Plasma Membrane Vesicles by Polyclonal Sera Directed against a 42 Kilodalton Plasma Membrane Polypeptide

Several polyclonal sera were raised in rabbits and in mice against putative sucrose carrier proteins, i.e. a 42 kilodalton (O Gallet, R Lemoine, C Larsson, S Delrot [1989] Biochim Biophys Acta 978: 56-64) and a 62 kD (KG Ripp, PV Viitanen, WD Hitz, VR Fransceschi [1988] Plant Physiol 88: 1435-1445) polypeptide of the plasma membrane. The effects of these sera on the active uptake of sucrose and of valine into purified plasma membrane vesicles from sugar beet (Beta vulgaris L.) leaves and roots were studied. At a dilution of 1/50, the anti-42 kilodalton sera consistently inhibited sucrose uptake in plasma membranes from leaves or from roots. They had no effect on valine uptake. Under the same experimental conditions, the anti-62 kilodalton sera had no effect on active uptake of sucrose. The data further support the view that a 42 kilodalton polypeptide is a component of the transport system mediating sucrose uptake across the plasma membrane of plant cells.

Construction of a functional lactose permease devoid of cysteine residues

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.

Organization and stability of a polytopic membrane protein: deletion analysis of the lactose permease of Escherichia coli

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.

Sequential truncation of the lactose permease over a three-amino acid sequence near the carboxyl terminus leads to progressive loss of activity and stability

Previous experiments are consistent with the notion that residues 396-401 (... SVFTLS ...) at the carboxyl terminus of the last putative transmembrane helix of the lactose (lac) permease of Escherichia coli are important for protection against proteolytic degradation and suggest that this region of the permease may be necessary for proper folding. Stop codons (TAA) have now been substituted sequentially for amino acid codons 396-401 in the lacY gene, and the termination mutants were expressed from the plasmid pT7-5. With respect to transport, permease truncated at residue 396 or 397 is completely defective, while molecules truncated at residues 398, 399, 400, and 401, respectively, exhibit 15-25%, 30-40%, 40-45%, and 70-100% of wild-type activity. As judged by pulse-chase experiments with [35S]methionine, wild-type permease or permease truncated at residue 401 is stable, while permease molecules truncated at position 400, 399, 398, 397, or 396 are degraded at increasingly rapid rates. The findings indicate that either the last turn of putative helix XII or the region immediately distal to helix XII is important for proper folding and protection against proteolytic degradation.

Role of proline residues in the structure and function of a membrane transport protein

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)

Kinetic analysis of lactose exchange in proteoliposomes reconstituted with purified lac permease

Lactose exchange catalyzed by purified lac permease reconstituted into proteoliposomes was analyzed with unequal concentrations of lactose on either side of the membrane and at low pH so as to prevent equilibration of the two pools. Exchange with external concentrations below 1.0 mM is a single-exponential process, and the apparent affinity constants for external and internal substrate are close to the apparent KMs reported for active transport and efflux, respectively [Viitanen, P.V., Garcia, M. L., & Kaback, H. R. (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 1629]. At external lactose concentrations above 1.0 mM, a second kinetic pathway becomes evident with an apparent affinity constant of about 6 mM which is similar to the apparent KM for facilitated influx. A second pathway is not observed with respect to internal lactose even when the concentration is increased up to 80 mM. Furthermore, high internal or external lactose concentrations do not inhibit the exchange reaction. Biphasic kinetics with respect to external lactose are retained in a mutant permease that catalyzes exchange but is defective in H(+)-coupled lactose transport. It is suggested that lac permease has more than one binding site and that this may be the underlying reason for the biphasic kinetics observed for both exchange and H(+)-coupled lactose transport.

Information content of amino acid residues in putative helix VIII of the lac permease from Escherichia coli

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.

In vivo expression of the lacY gene in two segments leads to functional lac permease

The lacY gene of Escherichia coli was cut into two approximately equal-size fragments with Afl II and subcloned individually or together under separate lac operator/promoters in plasmid pT7-5. Under these conditions, lac permease is expressed in two portions: (i) the N-terminal portion (the N terminus, the first six putative transmembrane helices, and most of putative loop 7) and (ii) the C-terminal portion (the last six putative transmembrane helices and the C terminus). Cells harboring pT7-5 encoding both fragments transport lactose at about 30% the rate of cells expressing intact permease to a comparable steady-state level of accumulation. In contrast, cells expressing either half of the permease independently do not transport lactose. As judged by [35S]methionine labeling and immunoblotting, intact permease is completely absent from the membrane of cells expressing lacY fragments either individually or together. Thus, transport activity must result from an association between independently synthesized pieces of lac permease. When the gene fragments are expressed individually, the N-terminal portion of the permease is observed inconsistently, and the C-terminal portion is not observed. When the gene fragments are expressed together, polypeptides identified as the N- and C-terminal moieties of the permease are found in the membrane. It is concluded that the N- or C-terminal halves of lac permease are proteolyzed when synthesized independently and that association between the two complementing polypeptides leads to a more stable, catalytically active complex.