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.

Structural features of the uniporter/symporter/antiporter superfamily.

The uniporter/symporter/antiporter superfamily is an evolutionarily related group of solute transporters. For the entire superfamily, we have used a new predictive program to identify the transmembrane domains. These transmembrane domains were then analyzed with regard to their overall hydrophobicity and amphipathicity. In addition, the lengths of the hydrophilic loops connecting the transmembrane domains were calculated. These data, together with structural information in the literature, were collectively used to produce a general model for the three-dimensional arrangement of the transmembrane domains.

Spectroscopic characterization of mutants supports the assignment of histidine-419 as the axial ligand of heme o in the binuclear center of the cytochrome bo ubiquinol oxidase from Escherichia coli.

The bo-type ubiquinol oxidase of Escherichia coli is a member of the superfamily of heme-copper oxidases which also includes the aa3-type cytochrome c oxidases. The oxygen-binding binuclear center of cytochrome bo is located in subunit I and consists of a heme (heme o; heme a3 in the aa3-type oxidases) and a copper (Cu(B)). Previous spectroscopic studies have shown that heme o is bound to the protein via a single histidine residue. Site-directed mutagenesis of conserved histidine residues in subunit I has identified two residues (H284 and H419) which are candidates for the ligand of heme o, while spectroscopic studies of mutants at H284 definitively demonstrated that this residue cannot be the axial ligand. Consequently, the single remaining conserved histidine in subunit I (H419) was assigned as the ligand for the heme of the binuclear center. In this paper, this assignment is tested by characterization of additional mutants in which the putative heme o axial ligand, H419, is replaced by other amino acids. All mutations at H419 result in the loss of enzyme activity. Analyses via UV-visible and Fourier transform infrared spectroscopies reveal that substantial perturbation has occurred at the binuclear center as a result of the amino acid substitutions. In contrast with the wild-type enzyme, the mutant enzymes bind very little carbon monoxide. Three other amino acid residues which are potential ligands for heme o are shown tob e nonessential for enzyme activity. Mutations in these residues do not perturb the UV-visible or FTIR spectroscopic characteristics of the enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)

Isolation of lactose permease mutants which recognize arabinose.

In the present study lactose permease mutants were isolated which recognize the monosaccharide, L-arabinose. Although the wild-type permease exhibits a poor recognition for L-arabinose, seven independent mutants were identified by their ability to grow on L-arabinose minimal plates. When subjected to DNA sequencing, it was found that all seven of these mutants were single-site mutations in which alanine 177 was changed to valine. The wild type and valine 177 mutant were then analyzed with regard to their abilities to recognize and transport monosaccharides and disaccharides. Free L-arabinose was shown to competitively inhibit [14C]-lactose transport yielding a Ki value of 121 mM for the Val177 mutant and a much higher value of 320 mM for the wild-type. Among several monosaccharides, D-glucose as well as L-arabinose inhibited lactose transport in the Val177 mutant to a significantly greater extent, while D-arabinose and D-xylose only caused a slight inhibition. On the other hand, kinetic studies with sugars which are normally recognized by the wild-type permease such as [14C]-galactose and [14C]-lactose revealed that the Val177 mutant and wild-type strains had similar transport characteristics for these two sugars. Overall, these results are consistent with the notion that the Val177 substitution causes an enhanced recognition for particular sugars (i.e. L-arabinose) but does not universally affect the recognition and unidirectional transport for all sugars. This idea is further supported by the observation that site-directed mutants containing isoleucine, leucine, phenylalanine, or proline at position 177 also were found to possess an enhanced recognition for L-arabinose.

Demonstration by FTIR that the bo-type ubiquinol oxidase of Escherichia coli contains a heme-copper binuclear center similar to that in cytochrome c oxidase and that proper assembly of the binuclear center requires the cyoE gene product.

Amino acid sequence data have revealed that the bo-type ubiquinol oxidase from Escherichia coli is closely related to the eukaryotic aa3-type cytochrome c oxidases. In the cytochrome c oxidases, the reduction of oxygen to water occurs at a binuclear center comprised of heme a3 and Cu(B). In this paper, Fourier transform infrared (FTIR) spectroscopy of CO bound to the enzyme is used to directly demonstrate that the E. coli bo-type ubiquinol oxidase also contains a heme-copper binuclear center. Photolysis of CO ligated to heme o at low temperatures (e.g., 30 K) results in formation of a CO-Cu complex, showing that there is a heme-Cu(B) binuclear center similar to that formed by heme a3 and Cu(B) in the eukaryotic oxidase. It is further demonstrated that the cyoE gene product is required for the correct assembly of this binuclear center, although this polypeptide is not required as a component of the active enzyme in vitro. The cyoE gene product is homologous to COX10, a nuclear gene product from Saccharomyces cerevisiae, which is required for the assembly of yeast cytochrome c oxidase. Deletion of the cyoE gene results in an inactive quinol oxidase that is, however, assembled in the membrane. FTIR analysis of bound CO shows that Cu(B) is present in this mutant but that the heme-Cu(B) binuclear center is abnormal. Analysis of the heme content of the membrane suggests that the cyoE deletion results in the insertion of heme B (protoheme IX) in the binuclear center, rather than heme O.(ABSTRACT TRUNCATED AT 250 WORDS)

Modified, large-scale purification of the cytochrome o complex (bo-type oxidase) of Escherichia coli yields a two heme/one copper terminal oxidase with high specific activity.

The cytochrome o complex is a bo-type ubiquinol oxidase in the aerobic respiratory chain of Escherichia coli. This complex has a close structural and functional relationship with the eukaryotic and prokaryotic aa3-type cytochrome c oxidases. The specific activity, subunit composition, and metal content of the purified cytochrome o complex are not consistent for different preparative protocols reported in the literature. This paper presents a relatively simple preparation of the enzyme starting with a strain of Escherichia coli which overproduces the oxidase. The pure enzyme contains four subunits by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Partial amino acid sequence data confirm the identities of subunit I, II, and III from the SDS-PAGE analysis as the cyoB, cyoA, and cyoC gene products, respectively. A slight modification of the purification protocol yields an oxidase preparation that contains a possible fifth subunit which may be the cyoE gene product. The pure four-subunit enzyme contains 2 equivs of iron but only 1 equiv of copper. There is no electron paramagnetic resonance detectable copper in the purified enzyme. Hence, the equivalent of CuA of the aa3-type cytochrome c oxidases is absent in this quinol oxidase. There is also no zinc in the purified quinol oxidase. Finally, monoclonal antibodies are reported that interact with subunit II. One of these monoclonals inhibits the quinol oxidase activity of the detergent-solubilized, purified oxidase. Hence, although subunit II does not contain CuA and does not interact with cytochrome c, it still must have an important function in the bo-type ubiquinol oxidase.