The conserved motif in hydrophilic loop 2/3 and loop 8/9 of the lactose permease of Escherichia coli. Analysis of suppressor mutations.

The major facilitator superfamily (MFS) of transport proteins, which includes the lactose permease of Escherichia coli, contains a 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. In three previous studies (Jessen-Marshall, A.E., & Brooker, R.J. 1996. J. Biol. Chem. 271:1400-1404; Jessen-Marshall, A.E., Parker, N., & Brooker, R.J. 1997. J. Bacteriol. 179:2616-2622; and Pazdernik, N., Cain, S.M., & Brooker, R.J. 1997. J. Biol. Chem. 272:26110-26116), suppressor mutations at twenty different sites were identified which restore function to mutant permeases that have deleterious mutations in the conserved loop 2/3 or loop 8/9 motif. In the current study, several of these second-site suppressor mutations have been separated from the original mutation in the conserved motif. The loop 2/3 suppressors were then coupled to a loop 8/9 mutation (P280L) and the loop 8/9 suppressors were coupled to a loop 2/3 mutation (i.e., G64S) to determine if the suppressors could restore function only to a loop 2/3 mutation, a loop 8/9 mutation, or both. The single parent mutations changing the first position in loop 2/3 (i.e., G64S) and loop 8/9 (i.e., P280L) had less than 4% lactose transport activity. Interestingly, most of the suppressors were very inhibitory when separated from the parent mutation. Two suppressors, A50T and G370V, restored substantial transport activity when individually coupled to the mutation in loop 2/3 and also when coupled to the corresponding mutation in loop 8/9. In other words, these suppressors could alleviate a defect imposed by mutations in either half of the permease. From a kinetic analysis, these suppressors were shown to exert their effects by increasing the V(max) values for lactose transport compared with the single G64S and P280L strains. These results are discussed within the context of our model in which the two halves of the lactose permease interact at a rotationally symmetrical interface, and that lactose transport is mediated by conformational changes at the interface.

Roles of charged residues in the conserved motif, G-X-X-X-D/E-R/K-X-G-[X]-R/K-R/K, of the lactose permease of Escherichia coli.

The lactose permease is a polytopic membrane protein that has a duplicated conserved motif, GXXX(D/E)(R/K)XG[X](R/K)(R/K), located in cytoplasmic loops 2/3 and 8/9. In the current study, the roles of the basic residues and the acidic residue were investigated in greater detail. Neutral substitutions of two positive charges in loop 2/3 were tolerated, while a triple mutant resulted in a complete loss of expression. Neutral substitutions of a basic residue in loop 8/9 (i.e., K289I) also diminished protein stability. By comparison, neutral substitutions affecting the negative charge in loop 2/3 had normal levels of expression, but were defective in transport. A double mutant (D68T/N284D), in which the aspartate of loop 2/3 was moved to loop 8/9, did not have appreciable activity, indicating that the negative charge in the conserved motif could not be placed in loop 8/9 to recover lactose transport activity. An analysis of site-directed mutants in loop 7/8 and loop 8/9 indicated that an alteration in the charge distribution across transmembrane segment 8 was not sufficient to alleviate a defect caused by the loss of a negative charge in loop 2/3. To further explore this phenomenon, the double mutant, D68T/N284D, was used as a parental strain to isolate suppressor mutations which restored function. One mutant was obtained in which an acidic residue in loop 11/12 was changed to a basic residue (i.e., Glu374 --> Lys). Overall, the results of this study suggest that the basic residues in the conserved motif play a role in protein insertion and/or stability, and that the negative charge plays a role in conformational changes.

Structural topology of transmembrane helix 10 in the lactose permease of Escherichia coli.

In the lactose permease of Escherichia coli, transmembrane helix 10 has been shown to be functionally important. The structure of this helix has been examined in greater detail in this study. A total of 46 substitution and 8 insertional mutants were constructed and analyzed along the entire length of transmembrane helix 10. The results identified amino acids that are tolerant of substitutions by a variety of amino acids. Since a number of these amino acids (Thr-320, Val-331, Phe-325, and Ile-317) are clustered in one region in a helical wheel projection of transmembrane helix 10, it seems likely that this face of helix 10 is interacting with the membrane. The channel lining domain is thought to consist of the helical face containing Glu-325, Leu-318, Leu-329, His-322, Val-315, Cys-333, Val-326, and Lys-319 based on the results here and from earlier findings. Deleterious mutations along this face tended to greatly increase the Km value for lactose transport with only minor effects on the Vmax. Analysis of insertional mutants revealed that perturbation of the spatial relationship between amino acids at the periplasmic edge is less deleterious than perturbation in the center of the helix or the cytoplasmic edge. Using all of the above information, a detailed structural topology of transmembrane helix 10 is proposed.

Functional role of arginine 302 within the lactose permease of Escherichia coli.

Within the lactose permease, an arginine residue is found on a transmembrane segment at position 302. Based upon the effects of mutations at or in the vicinity of Arg-302, this residue has been implicated to be involved with H+ and/or sugar recognition. To further elucidate the role of this residue, we have substituted Arg-302 with serine, histidine, and leucine via site-directed mutagenesis. All three of these substitutions result in an impaired ability to transport galactosides as evidenced by their poor growth on minimal plates supplemented with lactose or melibiose. Furthermore, in vitro transport assays revealed substantial alterations in the kinetic constants for downhill lactose transport. The wild-type strain exhibited a Km for lactose transport of 0.30 mM and a Vmax of 267 nmol of lactose/min.mg of protein. The Ser-302, His-302, and Leu-302 were observed to have Km values of 0.18, 2.3, and 2.8 mM, and Vmax values of 11.6, 56.4, and 22.0 nmol of lactose/min.mg of protein, respectively. In uphill transport assays, all three mutants were unable to accumulate beta-methyl-D-thiogalactoside. However, both the Ser-302 and His-302 mutants were able to accumulate lactose against a concentration gradient. During H+ transport assays, all three mutants were shown to transport H+ in conjunction with thiodigalactoside. In addition, the Ser-302 and His-302 strains exhibited small alkalinizations upon the addition of lactose. However, for the Leu-302 mutant, the addition of lactose did not result in a significant level of H+ transport. Finally, experiments were conducted which were aimed at measuring the ability of the mutant permeases to catalyze an H+ leak. In this regard, a comparison was made between the wild-type and mutant strains concerning their steady state pH gradient and their rates of H+ influx following oxygen pulses. The results of these experiments suggest that mutations at position 302 cause a sugar-dependent H+ leak.