The role of helix VIII in the lactose permease of Escherichia coli: I. Cys-scanning mutagenesis.

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.     

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)     

The role of helix VIII in the lactose permease of Escherichia coli: II. Site-directed sulfhydryl modification.

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.     

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.     

A conformational change in the lactose permease of Escherichia coli is induced by ligand binding or membrane potential.

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.     

Ligand-induced conformational changes in the lactose permease of Escherichia coli: evidence for two binding sites.

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)     

Suppressor analysis of mutations in the loop 2-3 motif of lactose permease: evidence that glycine-64 is an important residue for conformational changes.

A superfamily of transport proteins, which includes the lactose permease of Escherichia coli, contains a highly conserved motif, G-X-X-X-D/E-R/K-X-G-R/K-R/K, in the loops that connect transmembrane segments 2 and 3 and transmembrane segments 8 and 9. Previous analysis of this motif in the lactose permease (A. E. Jessen-Marshall, N. J. Paul, and R. J. Brooker, J. Biol. Chem. 270:16251-16257, 1995) has shown that the conserved glycine residue found at the first position in the motif (i.e., Gly-64) is important for transport function. Every substitution at this site, with the exception of alanine, greatly diminished lactose transport activity. In this study, three mutants in which glycine-64 was changed to cysteine, serine, and valine were used as parental strains to isolate 64 independent suppressor mutations that restored transport function. Of these 64 isolates, 39 were first-site revertants to glycine or alanine, while 25 were second-site mutations that restored transport activity yet retained a cysteine, serine, or valine at position 64. The second-site mutations were found to be located at several sites within the lactose permease (Pro-28 --> Ser, Leu, or Thr; Phe-29 --> Ser; Ala-50 --> Thr, Cys-154 --> Gly; Cys-234 --> Phe; Gln-241 --> Leu; Phe-261 --> Val; Thr-266 --> Iso; Val-367 --> Glu; and Ala-369 --> Pro). A kinetic analysis was conducted which compared lactose uptake in the three parental strains and several suppressor strains. The apparent Km values of the Cys-64, Ser-64, and Val-64 parental strains were 0.8 mM, 0.7 mM, and 4.6 mM, respectively, which was similar to the apparent Km of the wild-type permease (1.4 mM). In contrast, the Vmax values of the Cys-64, Ser-64, and Val-64 strains were sharply reduced (3.9, 10.1, and 13.2 nmol of lactose/min x mg of protein, respectively) compared with the wild-type strain (676 nmol of lactose/min x mg of protein). The primary effect of the second-site suppressor mutations was to restore the maximal rate of lactose transport to levels that were similar to the wild-type strains. Taken together, these results support the notion that Gly-64 in the wild-type permease is at a site in the protein which is important in facilitating conformational changes that are necessary for lactose translocation across the membrane. According to our tertiary model, this site is at an interface between the two halves of the protein.     

Lactose carrier mutants of Escherichia coli with changes in sugar recognition (lactose versus melibiose).

The purpose of this research was to identify amino acid residues that mediate substrate recognition in the lactose carrier of Escherichia coli. The lactose carrier transports the alpha-galactoside sugar melibiose as well as the beta-galactoside sugar lactose. Mutants from cells containing the lac genes on an F factor were selected by the ability to grow on succinate in the presence of the toxic galactoside beta-thio-o-nitrophenylgalactoside. Mutants that grew on melibiose minimal plates but failed to grow on lactose minimal plates were picked. In sugar transport assays, mutant cells showed the striking result of having low levels of lactose downhill transport but high levels of melibiose downhill transport. Accumulation (uphill) of melibiose was completely defective in all of the mutants. Kinetic analysis of melibiose transport in the mutants showed either no change or a greater than normal apparent affinity for melibiose. PCR was used to amplify the lacY DNA of each mutant, which was then sequenced by the Sanger method. The following six mutations were found in the lacY structural genes of individual mutants: Tyr-26-->Asp, Phe-27-->Tyr, Phe-29-->Leu, Asp-240-->Val, Leu-321-->Gln, and His-322-->Tyr. We conclude from these experiments that Tyr-26, Phe-27, Phe-29 (helix 1), Asp-240 (helix 7), Leu-321, and His-322 (helix 10) either directly or indirectly mediate sugar recognition in the lactose carrier of E. coli.     

lac permease of Escherichia coli: arginine-302 as a component of the postulated proton relay

The lac permease of Escherichia coli was modified by site-directed mutagenesis such that Arg-302 in putative helix IX was replaced with Leu. In addition, Ser-300 (helix IX) was replaced with Ala, and Lys-319 in putative helix X was replaced with Leu. Permease with Leu at position 302 manifests properties that are similar to those of permease with Arg in place of His-322 [Püttner, I. B., Sarkar, H. K., Poonian, M. S., & Kaback, H. R. (1986) Biochemistry 25, 4483]. Thus, permease with Leu-302 is markedly defective in active lactose transport, efflux, exchange, and counterflow but catalyzes downhill influx of lactose at high substrate concentrations without H+ translocation. In contrast, permease molecules with Ala at position 300 or Leu at position 319 catalyze lactose/H+ symport in a manner indistinguishable from that of wild-type permease. By molecular modeling, Arg-302 may be positioned in helix IX so that it faces the postulated His-322/Glu-325 ion pair in helix X. In this manner, the guanidino group in Arg-302 may interact with the imidazole of His-322 and thereby play a role in the H+ relay suggested to be involved in lactose/H+ symport [Carrasco, N., Antes, L. M., Poonian, M. S., & Kaback, H. R. (1986) Biochemistry 25, 4486].     

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.     

Lactose permease H+-lactose symporter: mechanical switch or Brownian ratchet?

Lactose permease structure is deemed consistent with a mechanical switch device for H(+)-coupled symport. Because the crystallography-assigned docking position of thiodigalactoside (TDG) does not make close contact with several amino acids essential for symport; the switch model requires allosteric interactions between the proton and sugar binding sites. The docking program, Autodock 3 reveals other lactose-docking sites. An alternative cotransport mechanism is proposed where His-322 imidazolium, positioned in the central pore equidistant (5-7 A) between six charged amino acids, Arg-302 and Lys-319 opposing Glu-269, Glu-325, Asp-237, and Asp-240, transfers a proton transiently to an H-bonded lactose hydroxyl group. Protonated lactose and its dissociation product H(3)O+ are repelled by reprotonated His-322 and drift in the electrostatic field toward the cytosol. This Brownian ratchet model, unlike the conventional carrier model, accounts for diminished symport by H322N mutant; how H322 mutants become uniporters; why exchanging Lys-319 with Asp-240 paradoxically inactivates symport; how some multiple mutants become revertant transporters; the raised export rate and affinity toward lactose of uncoupled mutants; the altered specificity toward lactose, melibiose, and galactose of some mutants, and the proton dissociation rate of H322 being 100-fold faster than the symport turnover rate.     

lac permease of Escherichia coli: histidine-322 and glutamic acid-325 may be components of a charge-relay system

When Glu-325 in the lac permease of Escherichia coli is replaced with Ala, lactose/H+ symport is abolished. Thus, the altered permease catalyzes neither uphill lactose accumulation nor efflux. Remarkably, however, permease with Ala-325 catalyzes exchange and counterflow at completely normal rates. Taken together with the results presented in the accompanying paper [Püttner, I. B., Sarkar, H. K., Poonian, M. S., & Kaback, H. R. (1986) Biochemistry (preceding paper in this issue)], the findings suggest that the His-322 and Glu-325 may be components of a charge-relay system that plays an important role in the coupled translocation of lactose and H+.     

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.     

lac permease of Escherichia coli: histidine-205 and histidine-322 play different roles in lactose/H+ symport

The lac permease of Escherichia coli was modified by site-directed mutagenesis such that His-205 or His-322 is replaced with either Asn or Gln. Permease with Asn or Gln in place of His-205 exhibits normal activity, while permease with Asn or Gln in place of His-322 exhibits no activity. The results are consistent with the interpretation that His-205 and His-322 play different roles in lactose/H+ symport, the former involving hydrogen bonding of the imidazole nitrogens and the latter requiring positive charge in the imidazole ring. In addition, it is demonstrated that permease with Arg in place of His-322 does not catalyze efflux, exchange, or counterflow. The observations, in conjunction with those in the accompanying paper [Carrasco, N., Antes, L. M., Poonian, M. S., & Kaback, H. R. (1986) Biochemistry (following paper in this issue)], suggest that His-322 plays an important role in H+ translocation, possibly as a component of a charge-relay system with Glu-325, a neighboring residue in helix 10.     

Depth of side-chain pocket in the S2 subsite of dipeptidyl peptidase IV

Kinetic studies of pig kidney dipeptidyl peptidase IV (dipeptidyl-peptide hydrolase, EC 3.4.14.5) were carried out using substrates possessing a side-chain of different length at the P2 position (or amino-terminal position in this case) such as Lys-, Arg-, Phe-, Met-, Ser-, His-, Glu- and Gly-Pro-pNA. The hydrolytic coefficient (Kcat/Km) has determined in the order Met- greater than Glu- greater than Ser- greater than His- greater than Phe- greater than Lys- greater than Gly- greater than Arg-, indicating a gradual increase with elongation of the side-chain from 0.03 to 0.60 nm followed by a decline when side-chain length approached 0.70 nm. Thus, the most probable depth of the side-chain pocket at the S2 subsite of the enzyme is proposed to be 0.50-0.60nm.     

Isolation of four novel tachykinins from frog (Rana catesbeiana) brain and intestine

In a survey for unknown bioactive peptides in frog (Rana catesbeiana) brain and intestine, we isolated four novel peptides that exhibit potent stimulant effects on smooth muscle preparation of guinea pig ileum. By microsequencing and synthesis, these peptides were identified as Lys- Pro- Ser- Pro- Asp- Arg- Phe- Tyr- Gly- Leu- Met- NH2 (ranatachykinin A), Tyr- Lys- Ser- Asp- Ser- Phe- Tyr- Gly- Leu- Met- NH2 (ranatachykinin B), His- Asn- Pro- Ala- Ser- Phe- Ile- Gly- Leu- Met- NH2 (ranatachykinin C) and Lys- Pro- Ans- Pro- Glu- Arg- Phe- Tyr- Ala- Pro- Met- NH2 (ranatachykinin D). Ranatachykinin (RTK) A, B and C conserve the C- terminal sequence, Phe- X- Gly- Leu- Met- NH2, which is common to known members of the tachykinin family. On the other hand, RTK-D has a striking feature in its C-terminal sequence, Phe- Tyr- Ala- Pro- Met- NH2, which has never been found in other known tachykinins, and may constitute a new subclass in the tachykinin family.     

Site-specific mutations in the N-terminal region of human C5a that affect interactions of C5a with the neutrophil C5a receptor.

C5a is an inflammatory mediator that evokes a variety of immune effector functions including chemotaxis, cell activation, spasmogenesis, and immune modulation. It is well established that the effector site in C5a is located in the C-terminal region, although other regions in C5a also contribute to receptor interaction. We have examined the N-terminal region (NTR) of human C5a by replacing selected residues in the NTR with glycine via site-directed mutagenesis. Mutants of rC5a were expressed as fusion proteins, and rC5a was isolated after factor Xa cleavage. The potency of the mutants was evaluated by measuring both neutrophil chemotaxis and degranulation (beta-glucuronidase release). Mutants that contained the single residue substitutions Ile-6-->Gly or Tyr-13-->Gly were reduced in potency to 4-30% compared with wild-type rC5a. Other single-site glycine substitutions at positions Leu-2, Ala-10, Lys-4, Lys-5, Glu-7, Glu-8, and Lys-14 showed little effect on C5a potency. The double mutant, Ile-6-->Gly/Tyr-13-->Gly, was reduced in potency to < 0.2%, which correlated with a correspondingly low binding affinity for neutrophil C5a receptors. Circular dichroism studies revealed a 40% reduction in alpha-helical content for the double mutant, suggesting that the NTR contributes stabilizing interactions that maintain local secondary or tertiary structure of C5a important for receptor interaction. We conclude that the N-terminal region in C5a is involved in receptor binding either through direct interaction with the receptor or by stabilizing a binding site elsewhere in the intact C5a molecule.     

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

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

Characterization of the gene for the chromosomal dihydrofolate reductase (DHFR) of Staphylococcus epidermidis ATCC 14990: the origin of the trimethoprim-resistant S1 DHFR from Staphylococcus aureus?

The gene for the chromosomally encoded dihydrofolate reductase (DHFR) of Staphylococcus epidermidis ATCC 14990 has been cloned and characterized. The structural gene encodes a polypeptide of 161 amino acid residues with a calculated molecular weight of 18,417. This trimethoprim-sensitive (Tmps) DHFR, SeDHFR, differs in only three amino acids (Val-31-->Ile, Gly-43-->Ala, and Phe-98-->Tyr) from the trimethoprim-resistant (Tmpr) S1 DHFR encoded by transposon Tn4003. Since in addition the S. epidermidis gene also forms part of an operon with thyE and open reading frame 140 as in Tn4003, the chromosomally located gene encoding the Tmps SeDHFR is likely to be the molecular origin of the plasmid-located gene encoding the Tmpr S1 DHFR. Site-directed mutagenesis and kinetic analysis of the purified enzymes suggest that a single Phe-->Tyr change at position 98 is the major determinant of trimethoprim resistance.     

Site-directed sulfhydryl labeling of helix IX in the lactose permease of Escherichia coli

Site-directed sulfhydryl modification of transmembrane helix IX in the lactose permease of Escherichia coli was studied in right-side-out membrane vesicles with the thiol-specific reagents N-[(14)C]ethylmaleimide (NEM) and methanethiosulfonate ethylsulfonate (MTSES) which are permeant and impermeant, respectively. Out of approximately 20 mutants with a single Cys residue at each position in the helix, only five mutants label with NEM. (i) Cys residues at positions 291, 308, and 310 label at 25 degrees C, and binding of substrate has no effect. (ii) Cys residues at positions 295 and 298 label only in the presence of substrate. NEM labeling at 0 degrees C indicates that alkylation of Cys residues at positions 295 and 308 is dependent on the thermal motion of the protein. In contrast, temperature has little effect on labeling of Cys residues at positions 291, 298, and 310. Interestingly, pretreatment with MTSES blocks NEM labeling of all the mutants. The findings demonstrate that the face of helix IX on which Arg302 is located is involved in ligand-induced conformational changes and accessible to water from the periplasmic surface of the membrane. Since Arg302 facilitates deprotonation of Glu325 (helix X) during turnover [Sahin-Tóth, M., and Kaback, H. R. (2001) Proc. Natl. Acad. Sci. U.S.A. 98, 6068-6073], the findings are consistent with the idea that this face of helix IX may comprise part of the H(+) translocation pathway.