Domain complementation studies reveal residues critical for the activity of the mannitol permease from Escherichia coli

This paper presents domain complementation studies in the mannitol transporter, EII^mtl, from Escherichia coli. EII^mtl is responsible for the transport and concomitant phosphorylation of mannitol over the cytoplasmic membrane. By using tryptophan-less EII^mtl as a basis, each of the four phenylalanines located in the cytoplasmic loop between putative transmembrane helices II and III in the membrane-embedded C domain were replaced by tryptophan, yielding the mutants W97, W114, W126, and W133. Except for W97, these single-tryptophan mutants exhibited a high, wild-type-like, binding affinity for mannitol. Of the four mutants, only W114 showed a high mannitol phosphorylation activity. EII^mtl is functional as a dimer and the effect of these mutations on the oligomeric activity was investigated via heterodimer formation (C/C domain complementation studies). The low phosphorylation activities of W126 and W133 could be increased 7-28 fold by forming heterodimers with either the C domain of W97 (IIC^mtlW97) or the inactive EII^mtl mutant G196D. W126 and W133, on the other hand, did not complement each other. This study points towards a role of positions 97, 126 and 133 in the oligomeric activation of EII^mtl. The involvement of specific residue positions in the oligomeric functioning of a sugar-translocating EII protein has not been presented before.     

Isolation of Escherichia coli Mannitol Permease,EIImtl, Trapped in Amphipol A8-35 and Fluorescein-Labeled A8-35

Amphipols (APols) are short amphipathic polymers that keep integral membrane proteins water-soluble while stabilizing them as compared to detergent solutions. In the present work, we have carried out functional and structural studies of a membrane transporter that had not been characterized in APol-trapped form yet, namely EII^mtl, a dimeric mannitol permease from the inner membrane of Escherichia coli. A tryptophan-less and dozens of single-tryptophan (Trp) mutants of this transporter are available, making it possible to study the environment of specific locations in the protein. With few exceptions, the single-Trp mutants show a high mannitol-phosphorylation activity when in membranes, but, as variance with wild-type EII^mtl, some of them lose most of their activity upon solubilization by neutral (PEG- or maltoside-based) detergents. Here, we present a protocol to isolate these detergent-sensitive mutants in active form using APol A8-35. Trapping with A8-35 keeps EII^mtl soluble and functional in the absence of detergent. The specific phosphorylation activity of an APol-trapped Trp-less EII^mtl mutant was found to be ~3× higher than the activity of the same protein in dodecylmaltoside. The preparations are suitable both for functional and for fluorescence spectroscopy studies. A fluorescein-labeled version of A8-35 has been synthesized and characterized. Exploratory studies were conducted to examine the environment of specific Trp locations in the transmembrane domain of EII^mtl using Trp fluorescence quenching by water-soluble quenchers and by the fluorescein-labeled APol. This approach has the potential to provide information on the transmembrane topology of MPs.     

Structural investigation of the transmembrane C domain of the mannitol permease from Escherichia coli using 5-FTrp fluorescence spectroscopy

The mannitol transporter EII(mtl) from Escherichia coli is responsible for the uptake of mannitol over the inner membrane and its concomitant phosphorylation. EII(mtl) is functional as a dimer and its membrane-embedded C domain, IIC(mtl), harbors one high affinity mannitol binding site. To characterize this domain in more detail the microenvironments of thirteen residue positions were explored by 5-fluorotryptophan (5-FTrp) fluorescence spectroscopy. Because of the simpler photophysics of 5-FTrp compared to Trp, one can distinguish between the two 5-FTrp probes present in dimeric IIC(mtl). At many labeled positions, the microenvironment of the 5-FTrps in the two protomers differs. Spectroscopic properties of three mutants labeled at positions 198, 251, and 260 show that two conserved motifs (Asn194-His195 and Gly254-Ile255-His256-Glu257) are located in well-structured parts of IIC(mtl). Mannitol binding has a large impact on the structure around position 198, while only minor changes are induced at positions 251 and 260. Phosphorylation of the cytoplasmic B domain of EII(mtl) is sensed by 5-FTrp at positions 30, 42, 251 and 260. We conclude that many parts of the IIC(mtl) structure are involved in the sugar translocation. The structure of EII(mtl), as investigated in this work, differs from the recently solved structure of a IIC protein transporting diacetylchitobiose, ChbC, and also belonging to the glucose superfamily of EII sugar transporters. In EII(mtl), the sugar binding site is more close to the periplasmic face and the structure of the 2 protomers in the dimer is different, while both protomers in the ChbC dimer are essentially the same.     

31phospho-NMR demonstration of phosphocysteine as a catalytic intermediate on the Escherichia coli phosphotransferase system EIIMtl

The mannitol-specific phosphotransferase system transport protein, Enzyme IIMtl, contains two catalytically important phosphorylated amino acid residues, both present on the cytoplasmic part of the enzyme. Recently, this portion has been subcloned, purified, and shown to be an enzymatically active domain. The N-terminal half has also been subcloned and shown to be the mannitol-binding domain. When combined the two domains catalyze mannitol phosphorylation at the expense of phospho-HPr (van Weeghel, R. P., Meyer, G. H., Pas, H. H., Keck, W. H., and Robillard, G. T., Biochemistry in press). The phospho-NMR spectrum of the purified phosphorylated cytoplasmic domain, taken at pH 8.0, shows two signals, one at -6.9 ppm compared with inorganic phosphate resulting from phosphohistidine and one at +11.9 ppm originating from phosphocysteine. Addition of mannitol plus membranes containing the N-terminal mannitol-binding domain results in the formation of mannitol 1-phosphate and the disappearance of the two signals at -6.9 and +11.9 ppm.     

5-Fluorotryptophan as dual probe for ground-state heterogeneity and excited-state dynamics in apoflavodoxin

The apoflavodoxin protein from Azotobacter vinelandii harboring three tryptophan (Trp) residues, was biosynthetically labeled with 5-fluorotryptophan (5-FTrp). 5-FTrp has the advantage that chemical differences in its microenvironment can be sensitively visualized via ¹⁹F NMR. Moreover, it shows simpler fluorescence decay kinetics. The occurrence of FRET was earlier observed via the fluorescence anisotropy decay of WT apoflavodoxin and the anisotropy decay parameters are in excellent agreement with distances between and relative orientations of all Trp residues. The anisotropy decay in 5-FTrp apoflavodoxin demonstrates that the distances and orientations are identical for this protein. This work demonstrates the added value of replacing Trp by 5-FTrp to study structural features of proteins via ¹⁹F NMR and fluorescence spectroscopy.     

Biophysical characterization of the domain association between cytosolic A and B domains of the mannitol transporter enzymes IIMtl in the presence and absence of a connecting linker

The mannitol transporter enzyme II^Mtl of the bacterial phosphotransferase system is a multi‐domain protein that catalyzes mannitol uptake and phosphorylation. Here we investigated the domain association between cytosolic A and B domains of enzyme II^Mtl, which are natively connected in Escherichia coli, but separated in Thermoanaerobacter tengcongensis. NMR backbone assignment and residual dipolar couplings indicated that backbone folds were well conserved between the homologous domains. The equilibrium binding of separately expressed domains, however, exhibited ～28‐fold higher affinity compared to the natively linked ones. Phosphorylation of the active site loop significantly contributed to the binding by reducing conformational dynamics at the binding interface, and a few key mutations at the interface were critical to further stabilize the complex by hydrogen bonding and hydrophobic interactions. The affinity increase implicated that domain associations in cell could be maintained at an optimal level regardless of the linker.     

Identification of the d-glucose-inhibitable cytochalasin B binding site as the glucose transporter in rat diaphragm plasma and microsomal membranes

[³H]Cytochalasin B binding and its competitive inhibition by d-glucose have been used to identify the glucose transporter in plasma and microsomal membranes prepared from intact rat diaphragm. Scatchard plot analysis of [³H]cytochalasin B binding yields a binding site with a dissociation constant of roughly 110 nM. Since the inhibition constant of cytochalasin B for d-glucose uptake by diaphragm plasma membranes is similar to this value, this site is identified as the glucose transporter. Plasma membranes prepared from diaphragms bind approx. 17 pmol of cytochalasin B/mg of membrane protein to the d-glucose-inhibitable site. If 280 nM (40 000 μunits/ml) insulin is present during incubation, cytochalasin B binding is increased roughly 2-fold without alteration in the dissociation constant of this site. In addition, membranes in the microsomal fraction contain 21 pmol of d-glucose-inhibitable cytochalasin B binding sites/mg of membrane protein. In the presence of insulin during incubation the number of these sites in the microsomal fraction is decreased to 9 pmol/mg of membrane protein. These results suggest that rat diaphragm contain glucose transporters with characteristics identical to those observed for the rat adipose cell glucose transporter. In addition, insulin stimulates glucose transport in rat diaphragm through a translocation of functionally identical glucose transporters from an intracellular membrane pool to the plasma membrane without an alteration in the characteristics of these sites.     

Identification of a key residue determining substrate affinity in the human glucose transporter GLUT1

Asn³³¹ in transmembrane segment 7 of the yeast Saccharomyces cerevisiae transporter Hxt2 has been identified as a single key residue for high-affinity glucose transport by comprehensive chimera approach. The glucose transporter GLUT1 of mammals belongs to the same major facilitator superfamily as Hxt2 and may therefore show a similar mechanism of substrate recognition. The functional role of Ile²⁸⁷ in human GLUT1, which corresponds to Asn³³¹ in Hxt2, was studied by its replacement with each of the other 19 amino acids. The mutant transporters were individually expressed in a recently developed yeast expression system for GLUT1. Replacement of Ile²⁸⁷ generated transporters with various affinities for glucose that correlated well with those of the corresponding mutants of the yeast transporter. Residues exhibiting high affinity for glucose were medium-sized, non-aromatic, uncharged and irrelevant to hydrogen-bond capability, suggesting an important role of van der Waals interaction. Sensitivity to phloretin, a specific inhibitor for the presumed exofacial glucose binding site, was decreased in two mutants, whereas that to cytochalasin B, a specific inhibitor for the presumed endofacial glucose binding site, was unchanged in the mutants. These results suggest that Ile²⁸⁷ is a key residue for maintaining high glucose affinity in GLUT1 as revealed in Hxt2 and is located at or near the exofacial glucose binding site.     

Identification of a Membrane-targeting Domain of the Transient Receptor Potential Canonical (TRPC)4 Channel Unrelated to Its Formation of a Tetrameric Structure

Canonical transient receptor potential (TRPC) channels are Ca²⁺-permeable nonselective cation channels that are activated by a wide variety of stimuli, including G protein-coupled receptors (GPCRs). The TRPC4 channel is expressed in a punctate distribution in the membrane. To identify the regulating region of the channel trafficking to the membrane, we generated deletion mutants of the TRPC4 channel. We determined that when either region that was downstream of the 20 amino acids of the N terminus or the 700–730 amino acids was deleted, the mutants were retained in the endoplasmic reticulum. By coexpression of the wild-type TRPC4 with deletion mutants, we found that the 23–29 amino acids of the N terminus regulate a membrane trafficking. Additionally, by the fluorescence resonance energy transfer (FRET) method, we found that the regions downstream of the 99 amino acid region of the N terminus and upstream of the 730 amino acid region in the C terminus produce assembly of the TRPC4 tetramers. We inferred the candidate proteins that regulate or interact with the 23–29 domain of TRPC4.     

Nitric Oxide Activation of Guanylate Cyclase Pushes the α1 Signaling Helix and the β1 Heme-binding Domain Closer to the Substrate-binding Site

The complete structure of the assembled domains of nitric oxide-sensitive guanylate cyclase (NOsGC) remains to be determined. It is also unknown how binding of NO to heme in guanylate cyclase is communicated to the catalytic domain. In the current study the conformational change of guanylate cyclase on activation by NO was studied using FRET. Endogenous tryptophan residues were used as donors, the substrate analog 2′-Mant-3′-dGTP as acceptor. The enzyme contains five tryptophan residues distributed evenly over all four functional domains. This provides a unique opportunity to detect the movement of the functional domains relative to the substrate-binding catalytic region. FRET measurements indicate that NO brings tryptophan 22 in the αB helix of the β₁ heme NO binding domain and tryptophan 466 in the second short helix of the α₁ coiled-coil domain closer to the catalytic domain. We propose that the respective domains act as a pair of tongs forcing the catalytic domain into the nitric oxide-activated conformation.     

Dissection of discrete kinetic events in the binding of antibiotics and substrates to the galactose-H+ symport protein,GalP, ofEscherichia coli

GalP is the membrane protein responsible for H⁺-driven uptake of D-galactose intoEscherichia coli. It is suggested to be the bacterial equivalent of the mammalian glucose transporter, GLUT1, since these proteins share sequence homology, recognise and transport similar substrates and are both inhibited by cytochalasin B and forskolin. The successful over-production of GalP to 35–55% of the total inner membrane protein ofE. coli has allowed direct physical measurements on isolated membrane preparations. The binding of the antibiotics cytochalasin B and forskolin could be monitored from changes in the inherent fluorescence of GalP, enabling derivation of a kinetic mechanism describing the interaction between the ligands and GalP. The binding of sugars to GalP produces little or no change in the inherent fluorescence of the transporter. However, the binding of transported sugars to GalP produces a large increase in the fluorescence of 8-anilino-1-naphthalene sulphonate (ANS) excited via tryptophan residues. This has allowed a binding step, in addition to two putative translocation steps, to be measured. From all these studies a basic kinetic mechanism for the transport cycle under non-energised conditions has been derived. The ease of genetical manipulation of thegalP gene inE. coli has been exploited to mutate individual amino acid residues that are predicted to play a critical role in transport activity and/or the recognition of substrates and antibiotics. Investigation of these mutant proteins using the fluorescence measurements should elucidate the role of individual residues in the transport cycle as well as refine the current model.Abbreviations GalP galactose-H⁺ transporter - AraE arabinose-H⁺ transporter - GLUT1 human erythrocyte glucose transporter requests for offprints: Krebs Institute for Biomolecular Research, Department of Molecular Biology and Biotechnology, University of Sheffield, Sheffield S10 2UH, UK     

Structural characterization of the PTS IIA and IIB proteins associated with pneumococcal fucose utilization

Streptococcus pneumoniae harbors a significant number of transporters, including phosphotransferase (PTS) systems, allowing the bacterium to utilize a number of different carbohydrates for metabolic and other purposes. The genes encoding for one PTS transport system in particular (EII^fuc) are found within a fucose utilization operon in S. pneumoniae TIGR4. Here, we report the three‐dimensional structures of IIA^fuc and IIB^fuc providing evidence that this PTS system belongs to the EII^man family. Additionally, the predicted metabolic pathway for this distinctive fucose utilization system suggests that EII^fuc transports the H‐disaccharide blood group antigen, which would represent a novel PTS transporter specificity. Proteins 2017; 85:963–968. © 2016 Wiley Periodicals, Inc.     

Squeezing at Entrance of Proton Transport Pathway in Proton-translocating Pyrophosphatase upon Substrate Binding

Homodimeric proton-translocating pyrophosphatase (H⁺-PPase; EC 3.6.1.1) is indispensable for many organisms in maintaining organellar pH homeostasis. This unique proton pump couples the hydrolysis of PP_i to proton translocation across the membrane. H⁺-PPase consists of 14–16 relatively hydrophobic transmembrane domains presumably for proton translocation and hydrophilic loops primarily embedding a catalytic site. Several highly conserved polar residues located at or near the entrance of the transport pathway in H⁺-PPase are essential for proton pumping activity. In this investigation single molecule FRET was employed to dissect the action at the pathway entrance in homodimeric Clostridium tetani H⁺-PPase upon ligand binding. The presence of the substrate analog, imidodiphosphate mediated two sites at the pathway entrance moving toward each other. Moreover, single molecule FRET analyses after the mutation at the first proton-carrying residue (Arg-169) demonstrated that conformational changes at the entrance are conceivably essential for the initial step of H⁺-PPase proton translocation. A working model is accordingly proposed to illustrate the squeeze at the entrance of the transport pathway in H⁺-PPase upon substrate binding.     

Regulatory activation is accompanied by movement in the C terminus of the Na-K-Cl cotransporter (NKCC1)

The Na-K-Cl cotransporter (NKCC1) is expressed in most vertebrate cells and is crucial in the regulation of cell volume and intracellular chloride concentration. To study the structure and function of NKCC1, we tagged the transporter with cyan (CFP) and yellow (YFP) fluorescent proteins at two sites within the C terminus and measured fluorescence resonance energy transfer (FRET) in stably expressing human embryonic kidney cell lines. Both singly and doubly tagged NKCC1s were appropriately produced, trafficked to the plasma membrane, and exhibited (86)Rb transport activity. When both fluorescent probes were placed within the same C terminus of an NKCC1 transporter, we recorded an 11% FRET decrease upon activation of the transporter. This result clearly demonstrates movement of the C terminus during the regulatory response to phosphorylation of the N terminus. When we introduced CFP and YFP separately in different NKCC1 constructs and cotransfected these in HEK cells, we observed FRET between dimer pairs, and the fractional FRET decrease upon transporter activation was 46%. Quantitatively, this indicates that the largest FRET-signaled movement is between dimer pairs, an observation supported by further experiments in which the doubly tagged construct was cotransfectionally diluted with untagged NKCC1. Our results demonstrate that regulation of NKCC1 is accompanied by a large movement between two positions in the C termini of a dimeric cotransporter. We suggest that the NKCC1 C terminus is involved in transport regulation and that dimerization may play a key structural role in the regulatory process. It is anticipated that when combined with structural information, our findings will provide a model for understanding the conformational changes that bring about NKCC1 regulation.     

Hydrophilic C-terminal domain of the Escherichia coli mannitol permease: phosphorylation, functional independence, and evidence for intersubunit phosphotransfer

The mannitol-specific enzyme II (mannitol permease) of the Escherichia coli phosphotransferase system (PTS) catalyzes the concomitant transport and phosphorylation of D-mannitol. Previous studies have shown that the mannitol permease (637 amino acid residues) consists of 2 structural domains of roughly equal size: an N-terminal, hydrophobic, membrane-bound domain and a C-terminal, hydrophilic, cytoplasmic domain. The C-terminal domain can be released from the membrane by mild proteolysis of everted membrane vesicles [Stephan, M.M., & Jacobson, G.R. (1986) Biochemistry 25, 8230-8234]. In this report, we show that phosphorylation of the intact permease by [32P]HPr (a general phosphocarrier protein of the PTS) followed by tryptic separation of the two domains resulted in labeling of only the C-terminal domain. Phosphorylation of the C-terminal domain occurred even in the complete absence of the N-terminal domain, showing that the former contains most, if not all, of the critical residues comprising the interaction site for phospho-HPr. The phosphorylated C-terminal domain, however, could not transfer its phospho group to mannitol, suggesting that the N-terminal domain is necessary for mannitol binding and/or phosphotransfer from the enzyme to the sugar. The elution profile of the C-terminal domain after molecular sieve chromatography showed that the isolated domain is monomeric, unlike the native permease which is likely a dimer in the membrane. Experiments employing a deletion mutation of the mtlA gene, which encodes a protein lacking the first phosphorylation site in the C-terminal domain (His-554) but retaining the second phosphorylation site (Cys-384), demonstrated that a phospho group could be transferred from phospho-HPr to Cys-384 of the deletion protein, and then to mannitol, only in the presence of the full-length permease.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cloning and molecular analysis of a mannitol operon of phosphoenolpyruvate-dependent phosphotransferase (PTS) type from <Emphasis Type="Italic">Vibrio cholerae</Emphasis> O395

A putative mannitol operon of the phosphoenolpyruvate phosphotransferase (PTS) type was cloned from Vibrio cholerae O395, and its activity was studied in Escherichia coli. The 3.9-kb operon comprising three genes is organized as mtlADR. Based on the sequence analysis, these were identified as genes encoding a putative mannitol-specific enzyme IICBA (EII^Mtl) component (MtlA), a mannitol-1-phosphate dehydrogenase (MtlD), and a mannitol operon repressor (MtlR). The transport of [³H]mannitol by the cloned mannitol operon in E. coli was 13.8 ± 1.4 nmol/min/mg protein. The insertional inactivation of EII^Mtl abolished mannitol and sorbitol transport in V. cholerae O395. Comparison of the mannitol utilization apparatus of V. cholerae with those of Gram-negative and Gram-positive bacteria suggests highly conserved nature of the system. MtlA and MtlD exhibit 75% similarity with corresponding sequences of E. coli mannitol operon genes, while MtlR has 63% similarity with MtlR of E. coli. The cloning of V. cholerae mannitol utilization system in an E. coli background will help in elucidating the functional properties of this operon.