Energetics of wild-type and mutant multidrug resistance secondary transporter LmrP of Lactococcus lactis

LmrP, a proton/multidrug antiporter of Lactococcus lactis, transports a variety of cationic substrates. Previously, two membrane-embedded acidic residues, Asp142 and Glu327, have been reported to be important for multidrug transport activity of LmrP. Here we show that neither Glu327 nor Asp142 is essential for ethidium binding but that Glu327 is a critical residue for the high affinity binding of Hoechst 33342. Substitution of these two residues, however, negatively influences the transport activity. The energetics of transport was studied of two closely related cationic substrates ethidium and propidium that carry one and two positive charges, respectively. Extrusion of monovalent ethidium is dependent on both the electrical membrane potential (Deltapsi) and transmembrane proton gradient (DeltapH), while extrusion of propidium predominantly depends on the DeltapH only. The LmrP mutants D142C and E327C, however, mediate electroneutral ethidium extrusion, but are unable to mediate DeltapH-dependent extrusion of propidium. These data indicate that Asp142 and Glu327 are involved in proton translocation.     

Two proton translocation pathways in a secondary active multidrug transporter

LmrP is a secondary active multidrug transporter from Lactococcus lactis. The protein belongs to the major facilitator superfamily and utilizes the electrochemical proton gradient (inside negative and alkaline) to extrude a wide range of lipophilic cations from the cell. Previous work has indicated that ethidium, a monovalent cationic substrate, is exported by LmrP by electrogenic antiport with two (or more) protons. This observation raised the question whether these protons are translocated sequentially along the same pathway, or through different routes. To address this question, we constructed a 3-D homology model of LmrP based on the high-resolution structure of the glycerol-3P/Pi antiporter GlpT from Escherichia coli, and we tested by mutagenesis the possible proton conduction points suggested by this model. Similar to the template, LmrP is predicted to contain an internal cavity formed at the interface between the two halves of the transporter. On the surface of this cavity lie two clusters of polar, aromatic and carboxylate residues with potentially important function in proton shuttling. Cluster 1 in the C-terminal half contains D235 and E327 in immediate proximity of each other, and is located near the apex of the cavity. Cluster 2 in the N-terminal half contains D142. Analyses of LmrP mutants containing charge-conservative or carboxyl-to-amide replacements at positions 142, 235 and 327 suggest that D142 is part of a dedicated proton translocation pathway in the ethidium translocation reaction. In contrast, D235 and E327 are part of an independent pathway, in which D235 interacts with protons. E327 appears to modulate the pKa of D235 and plays a role in the interaction with ethidium. These results are consistent with the proposal that major facilitator superfamily proteins consist of two membrane domains, one of which is involved in substrate binding and the other in ion coupling, and they indicate that there are two proton conduction pathways at play in the transport mechanism.     

Facilitated drug influx by an energy-uncoupled secondary multidrug transporter

The majority of bacterial multidrug resistance transporters belong to the class of secondary transporters. LmrP is a proton/drug antiporter of Lactococcus lactis that extrudes positively charged lipophilic substrates from the inner leaflet of the membrane to the external medium. This study shows that LmrP is a true secondary transporter. In the absence of a proton motive force, LmrP facilitates downhill fluxes of ethidium in both directions. These fluxes are inhibited by other substrates of LmrP. The cysteine-reactive agent p-chloromercuri-benzene sulfonate inhibits these fluxes in wild type LmrP but not in the cysteine-less LmrP C270A mutant. Cysteine mutagenesis of LmrP resulted in three mutants, D68C/C270A, D128C/C270A, and E327C/C270A, with an energy-uncoupled phenotype. Asp68 is located in the conserved motif GXXX(D/E)(R/K)XGRK for the major facilitator superfamily of secondary transporters and was found to play an important role in energy coupling, whereas the negatively charged residues Asp128 and Glu327 have indirect effects on the transport process. L. lactis strains expressing these uncoupled mutants of LmrP show an increased rate of ethidium influx and an increased drug susceptibility compared with cells harboring an empty vector. The rate of influx in these mutants is enhanced by a transmembrane electrical potential, inside negative. These observations suggest a new strategy for eliminating drug-resistant microbial pathogens, i.e. the design and use of modulators of secondary multidrug resistance transporters that uncouple drug efflux from proton influx, thereby allowing transmembrane electrical potential-driven influx of cationic drugs.     

Role of transmembrane segment 10 in efflux mediated by the staphylococcal multidrug transport protein QacA

The staphylococcal multidrug exporter QacA confers resistance to a wide range of structurally dissimilar monovalent and bivalent cationic antimicrobial compounds. To understand the functional importance of transmembrane segment 10, which is thought to be involved in substrate binding, cysteine-scanning mutagenesis was performed in which 35 amino acid residues in the putative transmembrane helix and its flanking regions were replaced in turn with cysteine. Solvent accessibility analysis of the introduced cysteine residues using fluorescein maleimide indicated that transmembrane segment 10 of QacA contains a 20-amino-acid hydrophobic core and may extend from Pro-309 to Ala-334. Phenotypic analysis and fluorimetric transport assays of these mutants showed that Gly-313 is important for the efflux of both monovalent and bivalent cationic substrates, whereas Asp-323 is only important for the efflux of bivalent substrates and probably forms part of the bivalent substrate-binding site(s) together with Met-319. Furthermore, the effects of N-ethyl-maleimide treatment on ethidium and 4',6-diamidino-2-phenylindole export mediated by the QacA mutants suggest that the face of transmembrane segment 10 that contains Asp-323 may also be close to the monovalent substrate-binding site(s), making this helix an integral component of the QacA multidrug-binding pocket.     

Glycine-rich transmembrane helix 10 in the staphylococcal tetracycline transporter TetA(K) lines a solvent-accessible channel

The staphylococcal TetA(K) tetracycline exporter is classified within the major facilitator superfamily of transport proteins and contains 14 alpha-helical transmembrane segments (TMS). Using cysteine-scanning mutagenesis, 27 amino acid residues across and flanking putative TMS 10 of the TetA(K) transporter were individually replaced with cysteine. The level of solvent accessibility to each of the targeted amino acid positions was determined as a measure of fluorescein maleimide reactivity and demonstrated that TMS 10 of TetA(K) has a cytoplasmic boundary at G313 and is likely to extend from at least V298 on the periplasmic side. TMS 10 was found to be amphiphilic containing at least partially solvent accessible amino acid residues along the length of one helical face, suggesting that this helix may line a solvent-exposed channel. Functional analyses of these cysteine mutants demonstrated a significant role for a number of amino acid residues, including a predominance of glycine residues which were further analyzed by alanine substitution. These residues are postulated to allow interhelical interactions between TMS 10 and distal parts of TetA(K) that are likely to be required for the tetracycline transport mechanism in TetA(K) and may be a general feature required by bacterial tetracycline transporters for activity.     

Evidence of ball-and-chain transport of ferric enterobactin through FepA

The Escherichia coli iron transporter, FepA, has a globular N terminus that resides within a transmembrane beta-barrel formed by its C terminus. We engineered 25 cysteine substitution mutations at different locations in FepA and modified their sulfhydryl side chains with fluorescein maleimide in live cells. The reactivity of the Cys residues changed, sometimes dramatically, during the transport of ferric enterobactin, the natural ligand of FepA. Patterns of Cys susceptibility reflected energy- and TonB-dependent motion in the receptor protein. During transport, a residue on the normally buried surface of the N-domain was labeled by fluorescein maleimide in the periplasm, providing evidence that the transport process involves expulsion of the globular domain from the beta-barrel. Porin deficiency much reduced the fluoresceination of this site, confirming the periplasmic labeling route. These data support the previously proposed, but never demonstrated, ball-and-chain theory of membrane transport. Functional complementation between a separately expressed N terminus and C-terminal beta-barrel domain confirmed the feasibility of this mechanism.     

Comparative site-directed mutagenesis in the catalytic amino acid triad in calicivirus proteases

Calicivirus proteases cleave the viral precursor polyprotein encoded by open reading frame 1 (ORF1) into multiple intermediate and mature proteins. These proteases have conserved histidine (His), glutamic acid (Glu) or aspartic acid (Asp), and cysteine (Cys) residues that are thought to act as a catalytic triad (i.e. general base, acid and nucleophile, respectively). However, is the triad critical for processing the polyprotein? In the present study, we examined these amino acids in viruses representing the four major genera of Caliciviridae: Norwalk virus (NoV), Rabbit hemorrhagic disease virus (RHDV), Sapporo virus (SaV) and Feline calicivirus (FCV). Using single amino‐acid substitutions, we found that an acidic amino acid (Glu or Asp), as well as the His and Cys in the putative catalytic triad, cannot be replaced by Ala for normal processing activity of the ORF1 polyprotein in vitro. Similarly, normal activity is not retained if the nucleophile Cys is replaced with Ser. These results showed the calicivirus protease is a Cys protease and the catalytic triad formation is important for protease activity. Our study is the first to directly compare the proteases of the four representative calicivirus genera. Interestingly, we found that RHDV and SaV proteases critically need the acidic residues during catalysis, whereas proteolytic cleavage occurs normally at several cleavage sites in the ORF1 polyprotein without a functional acid residue in the NoV and FCV proteases. Thus, the substrate recognition mechanism may be different between the SaV and RHDV proteases and the NoV and FCV proteases.     

A mutagenic study of beta-1,4-galactosyltransferases from Neisseria meningitidis

N-terminal His-tagged recombinant beta-1,4-galactosyltransferase from Neisseria meningitidis was expressed and purified to homogeneity by column chromatography using Ni-NTA resin. Mutations were introduced to investigate the roles of, Ser68, His69, Glu88, Asp90, and Tyr156, which are components of a highly conserved region in recombinant beta-1,4 galactosyltransferase. Also, the functions of three other cysteine residues, Cys65, Cys139, and Cys205, were investigated using site-directed mutagenesis to determine the location of the disulfide bond and the role of the sulfhydryl groups. Purified mutant galactosyltransferases, His69Phe, Glu88Gln and Asp90Asn completely shut down wild-type galactosyltransferase activity (1-3 %). Also, Ser68Ala showed much lower activity than wild-type galactosyltransferase (19 %). However, only the substitution of Tyr156Phe resulted in a slight reduction in galactosyltransferase activity (90 %). The enzyme was found to remain active when the cysteine residues at positions 139 and 205 were replaced separately with serine. However, enzyme reactivity was found to be markedly reduced when Cys65 was replaced with serine (27 %). These results indicate that conserved amino acids such as Cys65, Ser68, His69, Glu88, and Asp90 may be involved in the binding of substrates or in the catalysis of the galactosyltransferase reaction.     

Promiscuity in the geometry of electrostatic interactions between the Escherichia coli multidrug resistance transporter MdfA and cationic substrates

The Escherichia coli multidrug transporter MdfA contains a single membrane-embedded charged residue (Glu-26) that plays a critical role in the recognition of cationic substrates (Edgar, R., and Bibi, E. (1999) EMBO J. 18, 822-832). Using an inactive mutant (MdfA-E26T), we isolated a spontaneous second-site mutation (MdfA-E26T/V335E) that re-established the recognition of cationic drugs by the transporter. Only a negative charge at position 335 was able to restore the functioning of the inactive mutant MdfA-E26T. Intriguingly, the two genetically interacting residues are located at remote and distinct regions along the secondary structure of MdfA. Glu-26 is located in the periplasmic half of transmembrane helix 1, and as shown here, the complementing charge at position 335 resides within the cytoplasmic loop connecting transmembrane helices 10 and 11. The spatial relation between the two residues was investigated by cross-linking. A functional split version of MdfA devoid of cysteines was constructed and introduced with a cysteine pair at positions 26 and 335. Strikingly, the results indicate that residues 26 and 335 are spatially adjacent, suggesting that they both constitute parts of the multidrug recognition pocket of MdfA. The fact that electrostatic interactions are preserved with cationic substrates even if the critical acidic residue is placed on another face of the pocket reveals an additional dimension of promiscuity in multidrug recognition and transport.     

Basic residues R260 and K357 affect the conformational dynamics of the major facilitator superfamily multidrug transporter LmrP

Secondary-active multidrug transporters can confer resistance on cells to pharmaceuticals by mediating their extrusion away from intracellular targets via substrate/H(+)(Na(+)) antiport. While the interactions of catalytic carboxylates in these transporters with coupling ions and substrates (drugs) have been studied in some detail, the functional importance of basic residues has received much less attention. The only two basic residues R260 and K357 in transmembrane helices in the Major Facilitator Superfamily transporter LmrP from Lactococcus lactis are present on the outer surface of the protein, where they are exposed to the phospholipid head group region of the outer leaflet (R260) and inner leaflet (K357) of the cytoplasmic membrane. Although our observations on the proton-motive force dependence and kinetics of substrate transport, and substrate-dependent proton transport demonstrate that K357A and R260A mutants are affected in ethidium-proton and benzalkonium-proton antiport compared to wildtype LmrP, our findings suggest that R260 and K357 are not directly involved in the binding of substrates or the translocation of protons. Secondary-active multidrug transporters are thought to operate by a mechanism in which binding sites for substrates are alternately exposed to each face of the membrane. Disulfide crosslinking experiments were performed with a double cysteine mutant of LmrP that reports the substrate-stimulated transition from the outward-facing state to the inward-facing state with high substrate-binding affinity. In the experiments, the R260A and K357A mutations were found to influence the dynamics of these major protein conformations in the transport cycle, potentially by removing the interactions of R260 and K357 with phospholipids and/or other residues in LmrP. The R260A and K357A mutations therefore modify the maximum rate at which the transport cycle can operate and, as the transitions between conformational states are differently affected by components of the proton-motive force, the mutations also influence the energetics of transport.     

The Multidrug Transporter LmrP Protein Mediates Selective Calcium Efflux

LmrP is a major facilitator superfamily multidrug transporter from Lactococcus lactis that mediates the efflux of cationic amphiphilic substrates from the cell in a proton-motive force-dependent fashion. Interestingly, motif searches and docking studies suggested the presence of a putative Ca(2+)-binding site close to the interface between the two halves of inward facing LmrP. Binding experiments with radioactive (45)Ca(2+) demonstrated the presence of a high affinity Ca(2+)-binding site in purified LmrP, with an apparent K(d) of 7.2 μm, which is selective for Ca(2+) and Ba(2+) but not for Mn(2+), Mg(2+), or Co(2+). Consistent with our structure model and analogous to crystal structures of EF hand Ca(2+)-binding proteins, two carboxylates (Asp-235 and Glu-327) were found to be critical for (45)Ca(2+) binding. Using (45)Ca(2+) and a fluorescent Ca(2+)-selective probe, calcium transport measurements in intact cells, inside-out membrane vesicles, and proteoliposomes containing functionally reconstituted purified protein provided strong evidence for active efflux of Ca(2+) by LmrP with an apparent K(t) of 8.6 μm via electrogenic exchange with three or more protons. These observations demonstrate for the first time that LmrP mediates selective calcium/proton antiport and raise interesting questions about the functional and physiological links between this reaction and that of multidrug transport.     

Different functions of MdtB and MdtC subunits in the heterotrimeric efflux transporter MdtB(2)C complex of Escherichia coli

In contrast to homotrimeric transporters of the RND (resistance-nodulation-division) superfamily, which often conduct efflux transport of a wide range of substrates by the functionally rotating mechanism, the mechanism utilized by the heterotrimeric members of this family, which also perform multidrug efflux, is unclear. We examined one heterotrimeric transporter, the MdtB(2)C complex of Escherichia coli, by an extensive cysteine scanning mutagenesis of residues likely involved in ligand transport. Many such mutations in MdtC strongly decreased the level of cloxacillin transport, whereas mutations of corresponding residues in MdtB did not affect transport. Furthermore, many such residues in MdtC were covalently modified by fluorescein maleimide, which acted as a substrate and presumably produced labeling of the residues in the substrate path. In contrast, few residues in MdtB were labeled. Together with the previous data showing that the inactivation of proton translocation channel in MdtC has an only modest effect on transport yet in MdtB totally inactivated the activity, these results suggest that the two subunits, MdtB and MdtC, play very different roles, MdtC likely involved in substrate binding and transport and MdtB presumably inducing the conformational change needed for transport through proton translocation. Three-dimensional models of MdtB and MdtC, based on sequence homology with the AcrB transporter, also support this interpretation.     

Thermostabilization of recombinant human and bovine CuZn superoxide dismutases by replacement of free cysteines

Human CuZn superoxide dismutase (HSOD) has two free cysteines: a buried cysteine (Cys6) located in a beta-strand, and a solvent accessible cysteine (Cys111) located in a loop region. The highly homologous bovine enzyme (BSOD) has a single buried Cys6 residue. Cys6 residues in HSOD and BSOD were replaced by alanine and Cys111 residues in HSOD by serine. The mutant enzymes were expressed and purified from yeast and had normal specific activities. The relative resistance of the purified proteins to irreversible inactivation of enzymatic activity by heating at 70 degrees C was HSOD Ala6 Ser111 greater than BSOD Ala6 Ser109 greater than BSOD Cys6 Ser109 (wild type) greater than HSOD Ala6 Cys111 greater than HSOD Cys6 Ser111 greater than HSOD Cys111 (wild type). In all cases, removal of a free cysteine residue increased thermostability.     

Role of cysteine residues in Pseudomonas mevalonii 3-hydroxy-3-methylglutaryl-CoA reductase. Site-directed mutagenesis and characterization of the mutant enzymes

Each of the four identical subunits of Pseudomonas mevalonii 3-hydroxy-3-methylglutaryl (HMG)-CoA reductase contains two cysteine residues, Cys156 and Cys296 (Beach, M. J., and Rodwell, V. W. (1989) J. Bacteriol. 171, 2994-3001). Both are accessible to modification by sulfhydryl reagents under nondenaturing conditions (Jordan-Starck, T. C., and Rodwell, V. W. (1989) J. Biol. Chem. 264, 17913-17918). We used site-directed mutagenesis to construct three mutant enzymes in which alanine replaced either or both cysteine residues. Mutant enzymes C156A, C296A, and C156/296A were over-expressed in Escherichia coli and were found to be fully active. Following their purification, all four forms of the enzyme were compared with respect to their catalytic efficiency, their affinities for the substrates of all four catalyzed reactions, and for their sensitivity to inactivation by sulfhydryl reagents. Replacement of cysteine residues with alanine residues had no major effect on either the specific activity or the affinity of the enzymes for any substrate. The mutants catalyzed all four HMG-CoA reductase reactions as efficiently as did the wild-type enzyme, and coenzyme A stimulated mevaldehyde reduction to the same extent as for wild-type HMG-CoA reductase. Mutant C156A and the cysteine-free mutant C156/296A were not inactivated by 5,5'-dithiobis(2-nitrobenzoate). By contrast, mutant C296A was inactivated to the same extent as was the wild-type enzyme. Following treatment of the mutant enzymes with N-ethylmaleimide, the four reductase reactions catalyzed by mutant C296A were inactivated to the same extent as for the wild-type enzyme. Neither mutant C156A nor C156/296A was affected by this reagent. We conclude that the sulfhydryl reagent-reactive group whose derivatization leads to loss of enzymatic activity is Cys156. However, this residue is not an essential active site residue since neither substrate binding nor catalysis was affected when it was replaced by alanine. Possible roles of cysteine in maintaining structural stability are discussed.     

Recombinant lysine:N(6)-hydroxylase: effect of cysteine-->alanine replacements on structural integrity and catalytic competence

Recombinant lysine:N(6)-hydroxylase, rIucD, catalyzes the hydroxylation of L-lysine to its N(6)-hydroxy derivative, with NADPH and FAD serving as cofactors in the reaction. The five cysteine residues present in rIucD can be replaced, individually or in combination, with alanine without effecting a major change in the thermal stability, the affinity for L-lysine and FAD, as well as the k(cat) for mono-oxygenase activity of the protein. However, when the susceptibility to modification by either 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) or 2,6-dichlorophenol indophenol (DPIP) serves as the criterion for monitoring conformational change(s) in rIucD and its muteins, Cys146-->Ala and Cys166-->Ala substitutions are found to induce an enhancement in the reactivity of one of the protein's remaining cysteine residues with concomitant diminution of mono-oxygenase function. In addition, the systematic study of cysteine-->alanine replacement has led to the identification of rIucD's Cys166 as the exposed residue which is detectable during the reaction of the protein with DTNB but not with iodoacetate. Substitution of Cys51 of rIucD with alanine results in an increase in mono-oxygenase activity (approx. 2-fold). Such replacement, unlike those of other cysteine residues, also enables the covalent DPIP conjugate of the protein to accommodate FAD in its catalytic function. A possible role of rIucD's Cys51 in the modulation of its mono-oxygenase function is discussed.     

Three possible disulfides in the acetylcholine receptor alpha-subunit

The cysteinyl residues of the acetylcholine receptor alpha-subunit of Torpedo californica were analyzed. All seven cysteines could be accounted for. Three possible disulfide bridges and one unpaired cysteine were indicated. The disulfide linkages were as follows: Cys128 to Cys142; Cys192 to Cys193; Cys412 to Cys418 (Cys222 is unpaired). The identification of cysteinyl residues was accomplished by a modified protein blot procedure. Cysteinyl residues of intact nicotinic acetylcholine receptor were selectively biotinylated with 3-(N-maleimidopropionyl)biocytin and subsequently detected by the 125I-labeled avidin overlay of blotted Staphylococcus aureus V8 proteolyzed alpha-subunits. Two pairs of cysteines (Cys128/Cys142 and Cys412/Cys418) could be demonstrated only after Na(BH4) reduction of the acetylcholine receptor. Cysteine residues 192 and 193 are particularly sensitive to reduction; 0.1 mM dithiothreitol is sufficient.     

Analysis and separation of residues important for the chemoattractant and antimicrobial activities of beta-defensin 3

beta-Defensins are important in mammalian immunity displaying both antimicrobial and chemoattractant activities. Three canonical disulfide intramolecular bonds are believed to be dispensable for antimicrobial activity but essential for chemoattractant ability. However, here we show that HBD3 (human beta-defensin 3) alkylated with iodoactemide and devoid of any disulfide bonds is still a potent chemoattractant. Furthermore, when the canonical six cysteine residues are replaced with alanine, the peptide is no longer active as a chemoattractant. These findings are replicated by the murine ortholog Defb14. We restore the chemoattractant activity of Defb14 and HBD3 by introduction of a single cysteine in the fifth position (Cys V) of the beta-defensin six cysteine motif. In contrast, a peptide with a single cysteine at the first position (Cys I) is inactive. Moreover, a range of overlapping linear fragments of Defb14 do not act as chemoattractants, suggesting that the chemotactic activity of this peptide is not dependent solely on an epitope surrounding Cys V. Full-length peptides either with alkylated cysteine residues or with cysteine residues replaced with alanine are still strongly antimicrobial. Defb14 peptide fragments were also tested for antimicrobial activity, and peptides derived from the N-terminal region display potent antimicrobial activity. Thus, the chemoattractant and antimicrobial activities of beta-defensins can be separated, and both of these functions are independent of intramolecular disulfide bonds. These findings are important for further understanding of the mechanism of action of defensins and for therapeutic design.     

Site-specific fluorescence labelling of recombinant polyomavirus-like particles

For the development of gene therapy protocols based on polyomavirus-like particles, we describe a method for fluorescence labelling of virions in order to study virus-cell interactions preceding gene delivery. Site-specific fluorescence labelling of polyomavirus-like particles is achieved via a single cysteine residue and maleimide conjugates of fluorescence dyes (fluorescein, Texas Red). Polyomavirus-like particles can be assembled in vitro from recombinant capsomers produced in E. coli. Since the assembly process is independent of disulfide bond formation, all cysteine residues of the wild-type protein were replaced by serines, and a new unique cysteine residue was introduced for the attachment of the fluorescence marker.     

Molecular determinants of substrate selectivity of a novel organic cation transporter (PMAT) in the SLC29 family

Plasma membrane monoamine transporter (PMAT or ENT4) is a newly cloned transporter assigned to the equilibrative nucleoside transporter (ENT) family (SLC29). Unlike ENT1-3, PMAT mainly functions as a polyspecific organic cation transporter. In this study, we investigated the molecular mechanisms underlying the unique substrate selectivity of PMAT. By constructing chimeras between human PMAT and ENT1, we showed that a chimera consisting of transmembrane domains (TM) 1-6 of PMAT and TM7-11 of hENT1 behaved like PMAT, transporting 1-methyl-4-phenylpyridinium (MPP+, an organic cation) but not uridine (a nucleoside), suggesting that TM1-6 contains critical domains responsible for substrate recognition. To identify residues important for the cation selectivity of PMAT, 10 negatively charged residues were chosen and substituted with alanine. Five of the alanine mutants retained PMAT activity, and four were non-functional due to impaired targeting to the plasma membrane. However, alanine substitution at Glu(206) in TM5 abolished PMAT activity without affecting cell surface expression. Eliminating the charge at Glu(206) (E206Q) resulted in loss of organic cation transport activity, whereas conserving the negative charge (E206D) restored transporter function. Interestingly, mutant E206Q, which possesses the equivalent residue in ENT1, gained uridine transport activity. Thr(220), another residue in TM5, also showed an effect on PMAT activity. Helical wheel analysis of TM5 revealed a distinct amphipathic pattern with Glu(206) and Thr(220) clustered in the center of the hydrophilic face. In summary, our results suggest that Glu(206) functions as a critical charge sensor for cationic substrates and TM5 forms part of the substrate permeation pathway in PMAT.     

Catalytic and binding mutants of the junction-resolving enzyme endonuclease I of bacteriophage t7: role of acidic residues.

Endonuclease I is a 149 amino acid protein of bacteriophage T7 that is a Holliday junction-resolving enzyme, i.e. a four-way junction-selective nuclease. We have performed a systematic mutagenesis study of this protein, whereby all acidic amino acids have been individually replaced by other residues, mainly alanine. Out of 21 acidic residues, five (Glu20, Glu35, Glu65, Asp55 and Asp74) are essential. Replacement of these residues by other amino acids leads to a protein that is inactive in the cleavage of DNA junctions, but which nevertheless binds selectively to DNA junctions. The remaining 16 acidic residues can be replaced without loss of activity. The five critical amino acids are located within one section of the primary sequence. It is rather likely that their function is to bind one or more metal ions that coordinate the water molecule that brings about hydrolysis of the phosphodiester bond. We have also constructed a mutant of endonuclease I that lacks nine amino acids (six of which are arginine or lysine) at the C-terminus. Unlike the acidic point mutants, the C-terminal truncation is unable to bind to DNA junctions. It is therefore likely that the basic C-terminus is an important element in binding to the DNA junction.