Cysteine-scanning mutagenesis around transmembrane segments 1 and 11 and their flanking loop regions of Tn10-encoded metal-Tetracycline/H+ antiporter

Putative transmembrane helices (TM) 1 and 11 in the metal-tetracycline/H(+) antiporter are predicted to be close to each other on the basis of disulfide cross-linking experiments of the double-cysteine mutants in the periplasmic loop regions (Kubo, Y., Konishi, S., Kawabe, T., Nada, S., and Yamaguchi, A. (2000) J. Biol. Chem. 275, 5270-5274). In this study, each amino acid from Asn-2 to Gly-44 in the putative TM1 and loop1-2 regions or that from Ser-328 to Gly-366 in TM11 and its flanking regions was individually replaced with cysteine. With respect to the TM1 region, 10 mutants, from T5C to L14C, were all not reactive with N-ethylmaleimide (NEM), and from D15C to I22C, NEM-reactive and non-reactive mutations periodically appeared every two residues. Three mutants, M23C to V25C, were all NEM-reactive, but the degree of the latter two mutants was very low. Seven mutants, from L26C to E32C, were all highly reactive with NEM. Therefore, the region of TM1 is composed of the 21 amino acid residues from Thr-5 to Val-25. It is a partially amphiphilic helix, that is, the N-terminal (cytoplasmic) half is embedded in the hydrophobic interior, and the C-terminal (periplasmic) half faces a water-filled channel. With respect to TM11, nine mutants, from S328C to G336C, and six mutants, from L361C to G366C, were all reactive with NEM. On the other hand, out of the 24 mutants, from L337C to S360C, 17 were not reactive with NEM, and the 7 NEM-reactive mutants were scattered, indicating that this region is a transmembrane segment. The 7 residues from Val-347 to Phe-353 including Pro-350 formed a central hydrophobic core, and the 7 NEM-reactive mutations were periodically distributed in its flanking regions, indicating that both ends of TM11 face a water-filled channel. Ala-354 is located at about 1/3 of the length from the periplasmic end of TM11. Disulfide cross-linking experiments on double-cysteine mutants having the combination of A354C and a cysteine-scanning mutation in the loop1-2 region indicated that loop1-2 is very flexible and close to the periplasmic end of TM11. Tetracycline prevented the cross-linking formation between the periplasmic ends of TM1 and TM11; however, it did not affect the cross-linking between loop1-2 and TM11, indicating that the substrate-induced conformational change involves a shift in the relative locations of TM1 and TM11.     

The fourth transmembrane domain of the Helicobacter pylori Na+/H+ antiporter NhaA faces a water-filled channel required for ion transport

Cysteine-scanning mutagenesis was performed from Ser-130 to Leu-160 in the fourth transmembrane domain (TM4) of the Na+/H+ antiporter NhaA from Helicobacter pylori to determine the topology of each residue and to identify functionally important residues. All of the mutants were based on cysteine-less NhaA (Cys-less NhaA), which functions very similarly to the wild-type protein, and were expressed at a level similar to Cys-less NhaA. Discontinuity of [14C]N-ethylmaleimide (NEM)-reactive residues suggested that TM4 comprises residues Gly-135 to Val-156. Even within TM4, NEM reactivity was high for I136C, D141C to A143C, L146C, M150C, and G153C to R155C. These residues are thought to be located on one side of the -helical structure of TM4 and to face a putative water-filled channel. Pretreatment of intact cells with membrane-impermeable maleimide did not inhibit [14C]NEM binding to the NEM-reactive residues within TM4, suggesting that the putative channel opens toward the cytoplasm. NEM reactivity of the A143C mutant was significantly inhibited by Li+. The T140C and D141C mutants showed lower affinity for Na+ and Li+ as transport substrates, but their maximal antiporter velocities (Vmax) were relatively unaffected. Whereas the I142C and F144C mutants completely lost their Li+/H+ antiporter activity, I142C had a lower Vmax for the Na+/H+ antiporter. F144C exhibited a markedly lower Vmax and a partially reduced affinity for Na+. These results suggest that Thr-140, Asp-141, and Phe-144 are located in the end portion of a putative water-filled channel and may provide the binding site for Na+, Li+, and/or H+. Furthermore, residues Ile-142 to Phe-144 may be important for the conformational change that accompanies ion transport in NhaA.     

The first putative transmembrane segment of subunit c" (Vma16p) of the yeast V-ATPase is not necessary for function

The yeast vacuolar ATPase (V-ATPase) contains three proteolipid subunits: c (Vma3p), c' (Vma11p), and c" (Vma16p). Each subunit contains a buried glutamate residue that is essential for function, and these subunits are not able to substitute for each other in supporting activity. Subunits c and c' each contain four putative transmembrane segments (TM1-4), whereas subunit c" is predicted to contain five. To determine whether TM1 of subunit c" serves an essential function, a deletion mutant of Vma16p was constructed lacking TM1 (Vma16p-Delta TM1). Although this construct does not complement the loss of Vma3p or Vma11p, it does complement the loss of full-length Vma16p. Vacuoles isolated from the strain expressing Vma16p-Delta TM1 showed V-ATPase activity and proton transport greater than 80% relative to wild type and displayed wild type levels of subunits A and a, suggesting normal assembly of the V-ATPase complex. These results suggest that TM1 of Vma16p is dispensable for both activity and assembly of the V-ATPase. To obtain information about the topology of Vma16p, labeling of single cysteine-containing mutants using the membrane-permeable reagent 3-(N-maleimidylpropionyl)biocytin (MPB) and the -impermeable reagent 4-acetamido-4'-maleimidylstilbene-2,2'-disulfonic acid (AMS) was tested. Both the Cys-less form of Vma16p and eight single cysteine-containing mutants retained greater than 80% of wild type levels of activity. Of the eight mutants tested, two (S5C and S178C) were labeled by MPB. MPB-labeling of S5C was blocked by AMS in intact vacuoles, whereas S178C was blocked by AMS only in the presence of permeabilizing concentrations of detergent. In addition, a hemagglutinin epitope tag introduced into the C terminus of Vma16p was recognized by an anti-hemagglutinin antibody in intact vacuolar membranes, suggesting a cytoplasmic orientation for the C terminus. These results suggest that subunit c" contains four rather than five transmembrane segments with both the N and C terminus on the cytoplasmic side of the membrane.     

Transmembrane topography of the 100-kDa a subunit (Vph1p) of the yeast vacuolar proton-translocating ATPase.

The membrane topography of the yeast vacuolar proton-translocating ATPase a subunit (Vph1p) has been investigated using cysteine-scanning mutagenesis. A Cys-less form of Vph1p lacking the seven endogenous cysteines was constructed and shown to have 80% of wild type activity. Single cysteine residues were introduced at 13 sites within the Cys-less mutant, with 12 mutants showing greater than 70% of wild type activity. To evaluate their disposition with respect to the membrane, vacuoles were treated in the presence or absence of the impermeant sulfhydryl reagent 4-acetamido-4'-maleimidylstilbene-2,2'-disulfonic acid (AMS) followed by the membrane permeable sulfhydryl reagent 3-(N-maleimidylpropionyl) biocytin (MPB). Three of the 12 active cysteine mutants were not labeled by MPB. The mutants E3C, D89C, T161C, S266C, N447C, K450C, and S703C were labeled by MPB in an AMS-protectable manner, suggesting a cytoplasmic orientation, whereas G602C and S840C showed minimal protection by AMS, suggesting a lumenal orientation. Factor Xa cleavage sites were introduced at His-499, Leu-560, and Pro-606. Cleavage at 560 was observed in the absence of detergent, suggesting a cytoplasmic orientation for this site. Based on these results, we propose a model of the a subunit containing nine transmembrane segments, with the amino terminus facing the cytoplasm and the carboxyl terminus facing the lumen.     

Loop VIII/IX of the Na+-citrate transporter CitS of Klebsiella pneumoniae folds into an amphipathic surface helix

The sodium ion-dependent citrate transporter CitS of Klebsiella pneumoniae is a member of the 2-hydroxycarboxylate transporter (2HCT) family whose members transport divalent citrate in symport with two sodium ions. Profiles of the hydrophobic moment suggested the presence of an amphipathic helical structure in the cytoplasmic loop between transmembrane segments (TMSs) VIII and IX (the AH loop) in all members of the family. Cysteine-scanning mutagenesis was used to study the secondary structure of the AH loop. We have mutated 20 successive residues into cysteine residues, characterized each of the mutants for its transport activity, and determined the accessibility of the residues. Three of the mutants, G324C, F331C, and F332C, had very low citrate transport activity, and two others, I321C and S333C, exhibited significantly decreased activity after treatment of right-side-out membranes with membrane permeable thiol reagent N-ethylmaleimide (NEM), but not with membrane impermeable 4-acetamido-4'-maleimidylstilbene-2,2'-disulfonic acid (AmdiS) and [2-(trimethylammonium)ethyl]methanethiosulfonate (MTSET). No protection against NEM was observed with citrate or sodium ions. Labeling of the cysteine residues in the 20 mutants with the fluorescent probe fluorescein 5-maleimide, in membrane vesicles with an inverted orientation, resulted in a clear periodicity in the accessibility of the residues. Residues expected to be at the hydrophobic face of the putative alpha-helix were not accessible for the label, whereas those at the hydrophilic face were easily accessed and labeled. Pretreatment of whole cells and inside-out membranes expressing the mutants with the membrane impermeable reagent AmdiS confirmed the cytoplasmic localization of the AH region. It is concluded that the loop between TMSs VIII and IX folds into an amphipathic surface helix.     

Interacting helical surfaces of the transmembrane segments of subunits a and c' of the yeast V-ATPase defined by disulfide-mediated cross-linking

Proton translocation by the vacuolar (H+)-ATPase (or V-ATPase) has been shown by mutagenesis to be dependent upon charged residues present within transmembrane segments of subunit a as well as the three proteolipid subunits (c, c', and c"). Interaction between R735 in TM7 of subunit a and the glutamic acid residue in the middle of TM4 of subunits c and c' or TM2 of subunit c" has been proposed to be essential for proton release to the luminal compartment. In order to determine whether the helical face of TM7 of subunit a containing R735 is capable of interacting with the helical face of TM4 of subunit c' containing the essential glutamic acid residue (Glu-145), cysteine-mediated cross-linking between these subunits in yeast has been performed. Cys-less forms of subunits a and c' as well as forms containing unique cysteine residues were constructed, introduced together into a strain disrupted in both endogenous subunits, and tested for growth at neutral pH, for assembly competence and for cross-linking in the presence of cupric-phenanthroline by SDS-PAGE and Western blot analysis. Four different cysteine mutants of subunit a were each tested pairwise with ten different unique cysteine mutants of subunit c'. Strong cross-linking was observed for the pairs aS728C/c'I142C, aA731C/c'E145C, aA738C/c'F143C, aA738C/c'L147C, and aL739C/c'L147C. Partial cross-linking was observed for an additional 13 of 40 pairs analyzed. When arrayed on a helical wheel diagram, the results suggest that the helical face of TM7 of subunit a containing Arg-735 interacts with the helical face of TM4 of subunit c' centered on Val-146 and bounded by Glu-145 and Leu-147. The results are consistent with a possible rotational flexibility of one or both of these transmembrane segments as well as some flexibility of movement perpendicular to the membrane.     

Cysteine-scanning mutagenesis around transmembrane segment VI of Tn10-encoded metal-tetracycline/H(+) antiporter

Each amino acid in putative transmembrane helix VI and its flanking regions, from Ser-156 to Thr-185, of a Cys-free mutant of the Tn10-encoded metal-tetracycline/H(+) antiporter (TetA(B)) was individually replaced by Cys. All of the cysteine-scanning mutants showed a normal level of tetracycline resistance except for the S156C mutant, which showed moderate resistance, indicating that there is no essential residue located in this region. All 20 mutants from S159C to W178C showed no reactivity with N-ethylmaleimide (NEM), whereas the mutants of the flanking regions from S156C to H158C and F179C to T185C were highly or moderately reactive with NEM. These results indicate that like transmembrane helices III and IX, the transmembrane helix VI comprising residues Ser-159-Trp-178 is totally embedded in the hydrophobic environment.     

Single amino acid mutations in transmembrane domain 5 confer to the plasma membrane Ca2+ pump properties typical of the Ca2+ pump of endo(sarco)plasmic reticulum

Conserved residues in some of the transmembrane domains are proposed to mediate ion translocation by P-type pumps. The plasma membrane Ca(2+) pump (PMCA) lacks 2 of these residues in transmembrane domains (TM) 5 and 8. In particular, a glutamic acid (Glu-771) residue in TM5, which is proposed to be involved in the binding and transport of Ca(2+) by the sarcoplasmic reticulum Ca(2+) pump (SERCA), is replaced by an alanine (Ala-854) in the PMCA pump. Ala-854 has been mutated to Glu, Asp, or Gln; Glu-975 in TM8, which is an Ala in the SERCA pump, has been mutated to Gln, Asp, or Ala. The mutants have been expressed in three cell systems, with or without the help of viruses. When expressed in large amounts in Sf9 cells, the mutated pumps were isolated and analyzed in the purified state. Two of the three TM8 mutants were correctly delivered to the plasma membrane and were active. All the TM5 mutants were retained in the endoplasmic reticulum; two of them (A854Q and A854E) retained activity. Their properties (La(3+) sensitivity and decay of the phosphorylated intermediate, higher cooperativity of Ca(2+) binding with a Hill's coefficient approaching 2) differed from those of the expressed wild type PMCA pump, and resembled those of the SERCA pump.     

Membrane topology of a multidrug efflux transporter, AcrB, in Escherichia coli.

AcrA/B in Escherichia coli is a multicomponent system responsible for intrinsic resistance to a wide range of toxic compounds, and probably cooperates with the outer membrane protein TolC. In this study, acrAB genes were cloned from the E. coli W3104 chromosome. To determine the topology of the inner membrane component AcrB, we employed a chemical labeling approach to analyse mutants of AcrB in which a single cysteine residue had been introduced. The cysteine-free AcrB mutant, in which the two intrinsic Cys residues were replaced by Ala, retained full drug resistance. We constructed 33 cysteine mutants in which a single cysteine was introduced into each putative hydrophilic loop region of the cysteine-free AcrB. The binding of [(14)C]N-ethylmaleimide (NEM) to the Cys residue and the competition of NEM binding with the binding of a membrane-impermeant maleimide, 4-acetamide-4'-maleimidylstilbene-2,2'-disulfonic acid (AMS), in intact cells were investigated. The results revealed that the N- and C-terminals are localized on the cytoplasmic surface of the membrane and the two large loops are localized on the periplasmic surface of the membrane. The results supported the 12-membrane-spanning structure of AcrB. Three of the four short periplasmic loop regions were covered by the two large periplasmic loop domains and were not exposed to the water phase until one of the two large periplasmic loops was removed.     

Cytosolic half of transmembrane domain IV of the human bile acid transporter hASBT (SLC10A2) forms part of the substrate translocation pathway

We report the involvement of transmembrane domain 4 (TM4) of hASBT in forming the putative translocation pathway, using cysteine-scanning mutagenesis in conjunction with solvent-accessibility studies using the membrane-impermeant, sulfhydryl-specific methanethiosulfonate reagents. We individually mutated each of the 21 amino acids in TM4 to cysteine on a fully functional, MTS-resistant C270A-hASBT template. The single-cysteine mutants were expressed in COS-1 cells, and their cell surface expression levels, transport activities [uptake of the prototypical hASBT substrate taurocholic acid (TCA)], and sensitivities to MTS exposure were determined. Only P161 lacked cell-surface expression. Overall, cysteine replacement was tolerated at charged and polar residues, except for mutants I160C, Y162C, I165C, and G179C (相似文献   

Structure-function relationship of the fifth transmembrane domain in the Na+/H+ antiporter of Helicobacter pylori: Topology and function of the residues, including two consecutive essential aspartate residues

We examined the structure-function relationships of residues in the fifth transmembrane domain (TM5) of the Na+/H+ antiporter A (NhaA) from Helicobacter pylori (HP NhaA) by cysteine scanning mutagenesis. TM5 contains two aspartate residues, Asp-171 and Asp-172, which are essential for antiporter activity. Thirty-five residues spanning the putative TM5 and adjacent loop regions were replaced by cysteines. Cysteines replacing Val-162, Ile-165, and Asp-172 were labeled with NEM, suggesting that these three residues are exposed to a hydrophilic cavity within the membrane. Other residues in the putative TM domain, including Asp-171, were not labeled. Inhibition of NEM labeling by the membrane impermeable reagent AMS suggests that Val-162 and Ile-165 are exposed to a water filled channel open to the cytoplasmic space, whereas Asp-172 is exposed to the periplasmic space. D171C and D172C mutants completely lost Na+/H+ and Li+/H+ antiporter activities, whereas other Cys replacements did not result in a significant loss of these activities. These results suggest that Asp-171 and Asp-172 and the surrounding residues of TM5 provide an essential structure for H+ binding and Na+ or Li+ exchange. A168C and Y183C showed markedly decreased antiporter activities at acidic pH, whereas their activities were higher at alkaline pH, suggesting that the conformation of TM5 also plays a crucial role in the HP NhaA-specific acidic pH antiporter activity.     

Analysis of transmembrane domain 2 of rat serotonin transporter by cysteine scanning mutagenesis

The second transmembrane domain (TM2) of neurotransmitter transporters has been invoked to control oligomerization and surface expression. This transmembrane domain lies between TM1 and TM3, which have both been proposed to contain residues that contribute to the substrate binding site. Rat serotonin transporter (SERT) TM2 was investigated by cysteine scanning mutagenesis. Six mutants in which cysteine replaced an endogenous TM2 residue had low transport activity, and two were inactive. Most of the reduction in transport activity was due to decreased surface expression. In contrast, M124C and G128C showed increased activity and surface expression. Random mutagenesis at positions 124 and 128 revealed that hydrophobic residues at these positions also increased activity. When modeled as an alpha-helix, positions where mutation to cysteine strongly affects expression levels clustered on the face of TM2 surrounding the leucine heptad repeat conserved within this transporter family. 2-(Aminoethyl)-methanethiosulfonate hydrobromide (MTSEA)-biotin labeled A116C and Y136C but not F117C, M135C, or Y134C, suggesting that these residues may delimit the transmembrane domain. None of the cysteine substitution mutants from 117 through 135 were sensitive to [2-(trimethylammonium)ethyl]methanethiosulfonate bromide (MTSET) or MTSEA. However, treatment with MTSEA increased 5-hydroxytryptamine transport by A116C. Activation of A116C by MTSEA was observed only in mutants containing Cys to Ile mutation at position 357, suggesting that modification of Cys-116 activated transport by compensating for a disruption in transport in response to Cys-357 replacement. The reactivity of A116C toward MTSEA was substantially increased in the presence of substrates but not inhibitors. This increase required Na+ and Cl-, and was likely to result from conformational changes during the transport process.     

Conformationally sensitive residues in extracellular loop 5 of the Na+/dicarboxylate co-transporter

The Na+/dicarboxylate co-transporter, NaDC-1, from the kidney and small intestine, transports three sodium ions together with one divalent anion substrate, such as succinate2-. A previous study (Pajor, A. M. (2001) J. Biol. Chem. 276, 29961-29968), identified four amino acids, Ser-478, Ala-480, Ala-481, and Thr-482, near the extracellular end of transmembrane helix (TM) 9 that are likely to form part of the permeation pathway of the transporter. All four cysteine-substituted mutants were sensitive to inhibition by the membrane-impermeant reagent [2-(trimethylammonium)ethyl]-methanethiosulfonate (MTSET) and protected by substrate. In the present study, we continued the cysteine scan through extracellular loop 5 and TM10, from Thr-483 to Val-528. Most cysteine substitutions were well tolerated, although cysteine mutations of some residues, particularly within the TM, produced proteins that were not expressed on the plasma membrane. Six residues in the extracellular loop (Thr-483, Thr-484, Leu-485, Leu-487, Ile-489, and Met-493) were sensitive to chemical labeling by MTSET, depending on the conformational state of the protein. Transport inhibition by MTSET could be prevented by substrate regardless of temperature, suggesting that the likely mechanism of substrate protection is steric hindrance rather than large-scale conformational changes associated with translocation. We conclude that extracellular loop 5 in NaDC-1 appears to have a functional role, and it is likely to be located in or near the substrate translocation pore in the protein. Conformational changes in the protein affect the accessibility of the residues in extracellular loop 5 and provide further evidence of large-scale changes in the structure of NaDC-1 during the transport cycle.     

Cysteine scanning mutagenesis of helices 2 and 7 in GLUT1 identifies an exofacial cleft in both transmembrane segments

Cysteine scanning mutagenesis in conjunction with site-directed chemical modification of sulfhydryl groups by p-chloromercuribenzenesulfonate (pCMBS) or N-ethylmaleimide (NEM) was applied to putative transmembrane segments (TM) 2 and 7 of the cysteine-less glucose transporter GLUT1. Valid for both helices, the majority of cysteine substitution mutants functioned as active glucose transporters. The residues F72, G75, G76, G79, and S80 within helix 2 and G286 and N288 within helix 7 were irreplaceable because the mutant transporters displayed transport activities that were lower than 10% of Cys-less GLUT1. The indicated cluster of glycine residues within TM 2 is located on one face of the helix and may provide space for a bulky hydrophobic counterpart interacting with another transmembrane segment or lipid side chains. Characteristic for helix 7, three glutamine residues (Q279, Q282, and Q283) played an important role in transport activity of Cys-less GLUT1 because an individual replacement with cysteine reduced their transport rates by about 80%. ParaCMBS-sensitivity scanning of both transmembrane segments detected several membrane-harbored residues to be accessible to the extracellular aqueous solvent. The pCMBS-reactive sulfhydryl groups were located exclusively in the exofacial half of the plasma membrane and, when presented in a helical model, lie along one side of the helices. Taken together, transmembrane segments 2 and 7 form clefts accessible to the extracellular aqueous solvent. The lining residues are however excluded from interaction with intracellular solutes, as justified by microinjection of pCMBS into the cytoplasm of Xenopus oocytes.     

Environmental study of subunit i, a F(o) component of the yeast ATP synthase

The topology of subunit i, a component of the yeast F(o)F(1)-ATP synthase, was determined by the use of cysteine-substituted mutants. The N(in)-C(out) orientation of this intrinsic subunit was confirmed by chemical modification of unique cysteine residues with 4-acetamido-4'-maleimidylstilbene-2,2'-disulfonic acid. Near-neighbor relationships between subunit i and subunits 6, f, g, and d were demonstrated by cross-link formation following sulfhydryl oxidation or reaction with homobifunctional and heterobifunctional reagents. Our data suggest interactions between the unique membrane-spanning segment of subunit i and the first transmembranous alpha-helix of subunit 6 and a stoichiometry of 1 subunit i per complex. Cross-linked products between mutant subunits i and proteins loosely bound to the F(o)F(1)-ATP synthase suggest that subunit i is located at the periphery of the enzyme and interacts with proteins of the inner mitochondrial membrane that are not involved in the structure of the yeast ATP synthase.     

Transmembrane domain II of the Na+/proline transporter PutP of Escherichia coli forms part of a conformationally flexible,cytoplasmic exposed aqueous cavity within the membrane

The Na+/proline transporter PutP of Escherichia coli is a member of a large family of Na+/substrate symporters. Previous work on PutP suggests an involvement of the region ranging from Asp-55 to Gly-58 in binding of Na+ and/or proline (Pirch, T., Quick, M., Nietschke, M., Langkamp, M., Jung, H. (2002) J. Biol. Chem. 277, 8790-8796). In this study, a complete Cys scanning mutagenesis of transmembrane domain II (TM II) of PutP was performed to further elucidate the role of the TM in the transport process. Strong defects of PutP function were observed upon substitution of Ala-48, Ala-53, Trp-59, and Gly-63 by Cys in addition to the previously characterized residues Asp-55, Ser-57, and Gly-58. However, except for Asp-55 none of these residues proved essential for function. The activity of eight mutants was sensitive to N-ethylmaleimide inhibition with the sensitive positions clustering predominantly on a hydrophilic face in the cytoplasmic half of TM II. The same face was also highly accessible to the bulky sulfhydryl reagent fluorescein 5-maleimide in randomly oriented membrane vesicles, suggesting an unrestricted accessibility of the corresponding amino acid positions via an aqueous pathway. Na+ stimulated the reactivity of Cys toward fluorescein 5-maleimide at two positions while proline inhibited reaction of the sulfhydryl group at nine positions. Taken together, the results demonstrate that TM II of PutP is of particular functional importance. It is proposed that hydrophilic residues in the cytoplasmic half of TM II participate in the formation of an aqueous cavity in the membrane that allows Na+ and/or proline binding to residues located in the middle of the TM (e.g. Asp-55 and Ser-57). In addition, the data indicate that TM II participates in Na+- and proline-induced conformational alterations.     

Amino acid substitutions and alteration in cation specificity in the melibiose carrier of Escherichia coli

We isolated mutants of Escherichia coli which showed Li+-resistant growth on melibiose. The melibiose carrier of the mutants lost the ability to couple to H+, whereas it retained the ability to couple to Na+. The mutated gene, melB, of the mutants was cloned, and the nucleotide sequence was determined. The nucleotide replacements caused the following substitutions of amino acid residues in the melibiose carrier: Pro-142 with Ser, Leu-232 with Phe, or Ala-236 with Thr or Val. These amino acid residues are located in slightly hydrophobic regions of the melibiose carrier. The results provide strong support for the idea that such regions or their vicinities which contain those amino acid residues play an important role in H+ (or Li+) recognition or H+ (or Li+) transport by the melibiose carrier.     

The N-terminal region of the transmembrane domain of human erythrocyte band 3. Residues critical for membrane insertion and transport activity

We studied the role of the N-terminal region of the transmembrane domain of the human erythrocyte anion exchanger (band 3; residues 361-408) in the insertion, folding, and assembly of the first transmembrane span (TM1) to give rise to a transport-active molecule. We focused on the sequence around the 9-amino acid region deleted in Southeast Asian ovalocytosis (Ala-400 to Ala-408), which gives rise to nonfunctional band 3, and also on the portion of the protein N-terminal to the transmembrane domain (amino acids 361-396). We examined the effects of mutations in these regions on endoplasmic reticulum insertion (using cell-free translation), chloride transport, and cell-surface movement in Xenopus oocytes. We found that the hydrophobic length of TM1 was critical for membrane insertion and that formation of a transport-active structure also depended on the presence of specific amino acid sequences in TM1. Deletions of 2 or 3 amino acids including Pro-403 retained transport activity provided that a polar residue was located 2 or 3 amino acids on the C-terminal side of Asp-399. Finally, deletion of the cytoplasmic surface sequence G(381)LVRD abolished chloride transport, but not surface expression, indicating that this sequence makes an essential structural contribution to the anion transport site of band 3.     

The active site His-460 of human acyl-coenzyme A:cholesterol acyltransferase 1 resides in a hitherto undisclosed transmembrane domain

Human acyl-coenzyme A:cholesterol acyltransferase 1 (hACAT1) esterifies cholesterol at the endoplasmic reticulum (ER). We had previously reported that hACAT1 contains seven transmembrane domains (TMD) (Lin, S., Cheng, D., Liu, M. S., Chen, J., and Chang, T. Y. (1999) J. Biol. Chem. 274, 23276-23285) and nine cysteines. The Cys near the N-terminal is located at the cytoplasm; the two cysteines near the C-terminal form a disulfide bond and are located in the ER lumen. The other six free cysteines are located in buried region(s) of the enzyme (Guo, Z.-Y., Chang, C. C. Y., Lu, X., Chen, J., Li, B.-L., and Chang, T.-Y. (2005) Biochemistry 44, 6537-6548). In the current study, we show that the conserved His-460 is a key active site residue for hACAT1. We next performed Cys-scanning mutagenesis within the region of amino acids 354-493, expressed these mutants in Chinese hamster ovary cells lacking ACAT1, and prepared microsomes from transfected cells. The microsomes are either left intact or permeabilized with detergent. The accessibility of the engineered cysteines of microsomal hACAT1 to various maleimide derivatives, including mPEG(5000)-maleimide (large, hydrophilic, and membrane-impermeant), N-ethylmaleimide, 4-acetamido-4'-maleimidylstilbene-2,2'-disulfonic acid (small, hydrophilic, and ER membrane-permeant), and N-phenylmaleimide (small, hydrophobic, and ER membrane-permeant), were monitored by Western blot analysis. The results led us to construct a revised, nine-TMD model, with the active site His-460 located within a hitherto undisclosed transmembrane domain, between Arg-443 and Tyr-462.     

Critical amino acid residues in transmembrane domain 1 of the human organic anion transporter hOAT1

Human organic anion transporter 1 (hOAT1) belongs to a superfamily of organic anion transporters, which play critical roles in the body disposition of clinically important drugs, including anti-human immunodeficiency virus therapeutics, anti-tumor drugs, antibiotics, anti-hypertensives, and anti-inflammatories. Previously we suggested that the predicted transmembrane domain 1 (TM1) of hOAT1 might be important for its function. In the present study, we examined the role of each residue within TM1 of hOAT1 in substrate recognition and transport. Alanine scanning was used to construct mutants of hOAT1, and the uptake of model substrate para-aminohippurate was studied in COS-7 cells expressing the mutant transporters. This approach led to the discovery of two critical amino acid residues, Leu-30 and Thr-36. A substitution of Leu-30 or Thr-36 with alanine resulted in a complete loss of transport activities. We then further characterized Leu-30 and Thr-36 by mutagenizing these residues to amino acids with different physicochemical properties. Leu-30 was replaced with amino acids with varying sizes of side chains, including glycine, valine, and isoleucine. We showed that progressively smaller side chains at position 30 increasingly impaired hOAT1 function mainly because of the impaired surface expression of the transporter. Thr-36, another critical amino acid in TM1, was replaced by serine and cysteine. Similar to the substitution of Thr-36 by alanine, substitution by serine and cysteine at this position abolished transport activity without affecting the surface expression of the transporter. The fact that Thr-36 cannot be substituted with serine and that the side chains of alanine, serine, and cysteine are smaller than that of threonine by a methyl group indicate that both the methyl group and the hydroxyl group of Thr-36 could be critical for hOAT1 activity. Together we conclude that Leu-30 and Thr-36 play distinct roles in hOAT1 function. Leu-30 is important in targeting the transporter to the plasma membrane. In contrast, Thr-36 is critical for substrate recognition. The present study provided the first molecular evidence that transmembrane domain 1 is a critical determinant of hOAT1 function and may provide important insights into the structure-function relationships of the organic anion transporter family.