Ser57 in the Na+/proline permease of Escherichia coli is critical for high-affinity proline uptake

An artificial TCA cycle selects for efficient α-ketoglutarate dependent hydroxylase catalysis in engineered Escherichia coli

Amino acid hydroxylases depend directly on the cellular TCA cycle via their cosubstrate α-ketoglutarate (α-KG) and are highly useful for the selective biocatalytic oxyfunctionalization of amino acids. This study evaluates TCA cycle engineering strategies to force and increase α-KG flux through proline-4-hydroxylase (P4H). The genes sucA (α-KG dehydrogenase E1 subunit) and sucC (succinyl-CoA synthetase β subunit) were alternately deleted together with aceA (isocitrate lyase) in proline degradation-deficient Escherichia coli strains (ΔputA) expressing the p4h gene. Whereas, the ΔsucCΔaceAΔputA strain grew in minimal medium in the absence of P4H, relying on the activity of fumarate reductase, growth of the ΔsucAΔaceAΔputA strictly depended on P4H activity, thus coupling growth to proline hydroxylation. P4H restored growth, even when proline was not externally added. However, the reduced succinyl-CoA pool caused a 27% decrease of the average cell size compared to the wildtype strain. Medium supplementation partially restored the morphology and, in some cases, enhanced proline hydroxylation activity. The specific proline hydroxylation rate doubled when putP, encoding the Na⁺ /l-proline transporter, was overexpressed in the ΔsucAΔaceAΔputA strain. This is in contrast to wildtype and ΔputA single-knock out strains, in which α-KG availability obviously limited proline hydroxylation. Such α-KG limitation was relieved in the ΔsucAΔaceAΔputA strain. Furthermore, the ΔsucAΔaceAΔputA strain was used to demonstrate an agar plate-based method for the identification and selection of active α-KG dependent hydroxylases. This together with the possibility to waive selection pressure and overcome α-KG limitation in respective hydroxylation processes based on living cells emphasizes the potential of TCA cycle engineering for the productive application of α-KG dependent hydroxylases. Biotechnol. Bioeng. 2017;114: 1511-1520. © 2017 Wiley Periodicals, Inc.

Core Transmembrane Domain 6 Plays a Pivotal Role in the Transport Cycle of the Sodium/Proline Symporter PutP

Crystal structures of transporters with a LeuT-type structural fold assign core transmembrane domain 6 (TM6') a central role in substrate binding and translocation. Here, the function of TM6' in the sodium/proline symporter PutP, a member of the solute/sodium symporter family, was investigated. A complete scan of TM6' identified eight amino acids as particularly important for PutP function. Of these residues, Tyr-248, His-253, and Arg-257 impact sodium binding, whereas Arg-257 and Ala-260 may participate in interactions leading to closure of the inner gate. Furthermore, the previous suggestion of an involvement of Trp-244, Tyr-248, and Pro-252 in proline binding is further supported. In addition, substitution of Gly-245, Gly-247, and Gly-250 affects the amount of PutP in the membrane. A Cys accessibility analysis suggests an involvement of the inner half of TM6' in the formation of a hydrophilic pathway that is open to the inside in the absence of ligands and closed in the presence of sodium and proline. In conclusion, the results demonstrate that TM6' plays a central role in substrate binding and release on the inner side of the membrane also in PutP and extend the knowledge on functionally relevant amino acids in transporters with a LeuT-type structural fold.

Glu-311 in External Loop 4 of the Sodium/Proline Transporter PutP Is Crucial for External Gate Closure

The available structural information on LeuT and structurally related transporters suggests that external loop 4 (eL4) and the outer end of transmembrane domain (TM) 10' participate in the reversible occlusion of the outer pathway to the solute binding sites. Here, the functional significance of eL4 and the outer region of TM10' are explored using the sodium/proline symporter PutP as a model. Glu-311 at the tip of eL4, and various amino acids around the outer end of TM10' are identified as particularly crucial for function. Substitutions at these sites inhibit the transport cycle, and affect in part ligand binding. In addition, changes at selected sites induce a global structural alteration in the direction of an outward-open conformation. It is suggested that interactions between the tip of eL4 and the peptide backbone at the end of TM10' participate in coordinating conformational alterations underlying the alternating access mechanism of transport. Together with the structural information on LeuT-like transporters, the results further specify the idea that common design and functional principles are maintained across different transport families.

Biosynthesis of Proline

Proline was among the last biosynthetic precursors to have its biosynthetic pathway unraveled. This review recapitulates the findings on the biosynthesis and transport of proline. Glutamyl kinase (GK) catalyzes the ATP-dependent phosphorylation of L-glutamic acid. Purification of γ-GK from Escherichia coli was facilitated by the expression of the proB and proA genes from a high-copy-number plasmid and the development of a specific coupled assay based on the NADPH-dependent reduction of GP by γ-glutamyl phosphate reductase (GPR). GPR catalyzes the NADPH-dependent reduction of GP to GSA. Site directed mutagenesis was used to identify residues that constitute the active site of E. coli GK. This analysis indicated that there is an overlap between the binding sites for glutamate and the allosteric inhibitor proline, suggesting that proline competes with the binding of glutamate. The review also summarizes the genes involved in the metabolism of proline in E. coli and Salmonella. Among the completed genomic sequences of Enterobacteriaceae, genes specifying all three proline biosynthetic enzymes can be discerned in E. coli, Shigella, Salmonella enterica, Serratia marcescens, Erwinia carotovora, Yersinia, Photorhabdus luminescens, and Sodalis glossinidius strain morsitans. The intracellular proline concentration increases with increasing external osmolality in proline-overproducing mutants. This apparent osmotic regulation of proline accumulation in the overproducing strains may be the result of increased retention or recapture of proline, achieved by osmotic stimulation of the ProP or ProU proline transport systems. A number of proline analogs can be incorporated into proteins in vivo or in vitro.

The sodium/multivitamin transporter: a multipotent system with therapeutic implications

The Na(+)/multivitamin transporter (SMVT) is a member of the solute:sodium symporter family that catalyzes the Na(+)-dependent uptake of the structurally diverse water-soluble vitamins pantothenic acid (vitamin B5) and biotin (vitamin H), α-lipoic acid-a vitamin-like substance with strong antioxidant properties-and iodide. The organic substrates of SMVT play central roles in the cellular metabolism and are, therefore, essential for normal human health and development. For example, biotin deficiency leads to growth retardation, dermatological disorders, and neurological disorders. Animal studies have shown that biotin deficiency during pregnancy is directly correlated to embryonic growth retardation, congenital malformation, and death of the embryo. This chapter focuses on the structural and functional features of the human isoform of SMVT (hSMVT); the discovery of which was greatly facilitated by the cloning and expression of hSMVT in tractable expression systems. Special emphasis will be given to mechanistic implications of the transport process of hSMVT that will inform our understanding of the molecular determinants of hSMVT-mediated transport in dynamic context to alleviate the development and optimization of hSMVT as a multipotent platform for drug delivery.

Identification of a second substrate-binding site in solute-sodium symporters

The structure of the sodium/galactose transporter (vSGLT), a solute-sodium symporter (SSS) from Vibrio parahaemolyticus, shares a common structural fold with LeuT of the neurotransmitter-sodium symporter family. Structural alignments between LeuT and vSGLT reveal that the crystallographically identified galactose-binding site in vSGLT is located in a more extracellular location relative to the central substrate-binding site (S1) in LeuT. Our computational analyses suggest the existence of an additional galactose-binding site in vSGLT that aligns to the S1 site of LeuT. Radiolabeled galactose saturation binding experiments indicate that, like LeuT, vSGLT can simultaneously bind two substrate molecules under equilibrium conditions. Mutating key residues in the individual substrate-binding sites reduced the molar substrate-to-protein binding stoichiometry to ~1. In addition, the related and more experimentally tractable SSS member PutP (the Na(+)/proline transporter) also exhibits a binding stoichiometry of 2. Targeting residues in the proposed sites with mutations results in the reduction of the binding stoichiometry and is accompanied by severely impaired translocation of proline. Our data suggest that substrate transport by SSS members requires both substrate-binding sites, thereby implying that SSSs and neurotransmitter-sodium symporters share common mechanistic elements in substrate transport.

Extracellular loop 4 of the proline transporter PutP controls the periplasmic entrance to ligand binding sites

The Na(+)/proline symporter (PutP), like several other Na(+)-coupled symporters, belongs to the so-called LeuT-fold structural family, which features ten core transmembrane domains (cTMs) connected by extra- and intracellular loops. The role of these loops has been discussed in context with the gating function in the alternating access model of secondary active transport processes. Here we report the complete spin-labeling site scan of extracellular loop 4 (eL4) in PutP that reveals the presence of two α-helical segments, eL4a and eL4b. Among the eL4 residues that are directly implicated in the functional dynamics of the transporter, Phe314 in eL4b anchors the loop by means of hydrophobic contacts to cTM1 close to the ligand binding sites. We propose that ligand-induced conformational changes at the binding sites are transmitted via the anchoring residue to eL4 and through eL4 further to adjacent cTMs, leading to closure of the extracellular gate.

The sodium/proline transporter PutP of Helicobacter pylori

Helicobacter pylori is cause of chronic gastritis, duodenal ulcer and gastric carcinoma in humans. L-proline is a preferred energy source of the microaerophilic bacterium. Previous analyses revealed that HpputP and HpputA, the genes that are predicted to play a central role in proline metabolism as they encode for the proline transporter and proline dehydrogenase, respectively, are essential for stomach colonization. Here, the molecular basis of proline transport in H. pylori by HpPutP was investigated experimentally for the first time. Measuring radiolabeled substrate transport in H. pylori and E. coli heterologously expressing HpputP as well as in proteoliposomes reconstituted with HpPutP, we demonstrate that the observed proline transport in H. pylori is mediated by HpPutP. HpPutP is specific and exhibits a high affinity for L-proline. Notably, L-proline transport is exclusively dependent on Na⁺ as coupling ion, i.e., Na⁺/L-proline symport, reminiscent to the properties of PutP of E. coli even though H. pylori lives in a more acidic environment. Homology model-based structural comparisons and substitution analyses identified amino acids crucial for function. HpPutP-catalyzed proline uptake was efficiently inhibited by the known proline analogs 3,4-dehydro-D,L-proline and L-azetidine-2-carboxylic acid.

Conserved tyrosine in the first transmembrane segment of solute:sodium symporters is involved in Na+-coupled substrate co-transport

Solute:sodium symporters (SSSs) transport vital molecules across the plasma membrane of all living organisms. vSGLT, the Na(+)/galactose transporter of Vibrio parahemeolyticus, is the only SSS for which high resolution structural information is available, revealing a LeuT-like fold and a Na(+)-binding site analogous to the Na2 site of LeuT. Whereas the core transmembrane segments (TMs) of SSSs share high structural similarity with other transporters of LeuT-like fold, TM1 does not correspond to any TM in those structural homologs and was only resolved for the backbone atoms in the initial vSGLT structure (Protein Data Bank code 3DH4). To assess the role of TM1 in Na(+)-coupled substrate symport by the SSSs, here we have studied the role of a conserved residue in TM1 by computational modeling in conjunction with radiotracer transport and binding studies. Based on our sequence alignment and much topological data for homologous PutP, the Na(+)/proline transporter, we have simulated a series of vSGLT models with shifted TM1 residue assignments. We show that in two converged vSGLT models that retained the original TM1 backbone conformation, a conserved residue, Tyr-19, is associated with the Na(+) binding interaction network. In silico and in vitro mutagenesis of homologous Tyr-14 in PutP revealed the involvement of this conserved residue in Na(+)-dependent substrate binding and transport. Thus, our combined computational and experimental data provide the first clues about the importance of a conserved residue in TM1, a unique TM in the proteins with LeuT-like fold, in the Na(+)-coupled symport mechanism of SSSs.

Homology model of the Na+/proline transporter PutP of Escherichia coli and its functional implications

Na(+)/solute symporters are essential membrane integrated proteins that couple the flow of Na(+) ions driven by electrochemical Na(+) gradients to the transport of solutes across biological membranes. Here, we used a combination of molecular modeling techniques and evolutionary conservation analysis to construct and validate a first model of the Na(+)/proline symporter PutP of Escherichia coli based on the crystal structure of the bacterial Na(+)/galactose symporter vSGLT. Ligand docking experiments were employed to gain information about residues involved in proline binding. The proposed model is consistent with the available experimental data and was further validated by amino acid substitutions and kinetic and protein chemical analyses. Combination of the results of molecular modeling and functional studies predicts the location and organization of the Na(+) and proline binding sites. Remarkably, as proposed computationally and discovered here experimentally, residues Y140, W244, and Y248 of transmembrane segments 4 and 7 are found to be particularly important for PutP function and suggested to participate in proline binding and/or gating.

Amino acid substitutions in transmembrane domains 9 and 10 of GerVB that affect the germination properties of Bacillus megaterium spores

The molecular basis for differences in germinant recognition of Bacillus megaterium QM B1551 spores containing the GerVB and/or GerUB receptor proteins has been examined by site-directed mutagenesis and the construction of cross-homologue chimeras. Focusing on nonconserved residues predicted to reside in transmembrane domains 9 and 10, we demonstrate that GerVB residues Ser319 and Leu345 are of particular importance in defining the specificity and apparent affinity of the receptor for germinants. Kinetic analyses of mutants with different amino acid substitutions at these positions indicate that Ser319 and Leu345 are not involved directly in the binding of germinants, but probably reside in regions of the receptor where structural perturbations can affect the conformation of, or access to, germinant binding sites. Position 345 is also shown to be of importance in GerUB, where the F345A mutation severely impairs receptor function. Functionality is restored in the GerUB Ala345 background by substituting putative outer-loop residues adjacent to TM10 for the corresponding residues in GerVB, indicating that a degree of structural coordination between these regions is important to receptor function.

Genetic analysis of Vibrio cholerae monolayer formation reveals a key role for DeltaPsi in the transition to permanent attachment

A bacterial monolayer biofilm is a collection of cells attached to a surface but not to each other. Monolayer formation is initiated when a bacterial cell forms a transient attachment to a surface. While some transient attachments are broken, others transition into the permanent attachments that define a monolayer biofilm. In this work, we describe the results of a large-scale, microscopy-based genetic screen for Vibrio cholerae mutants that are defective in formation of a monolayer biofilm. This screen identified mutations that alter both transient and permanent attachment. Transient attachment was somewhat slower in the absence of flagellar motility. However, flagellar mutants eventually formed a robust monolayer. In contrast, in the absence of the flagellar motor, monolayer formation was severely impaired. A number of proteins that modulate the V. cholerae ion motive force were also found to affect the transition from transient to permanent attachment. Using chemicals that dissipate various components of the ion motive force, we discovered that dissipation of the membrane potential (DeltaPsi) completely blocks the transition from transient to permanent attachment. We propose that as a bacterium approaches a surface, the interaction of the flagellum with the surface leads to transient hyperpolarization of the bacterial cell membrane. This, in turn, initiates the transition to permanent attachment.

Function of transmembrane domain IX in the Na+/proline transporter PutP

Selected residues of transmembrane domain (TM) IX were previously shown to play key roles in ligand binding and transport in members of the Na(+)/solute symporter family. Using the Na(+)/proline transporter PutP as a model, a complete Cys scanning mutagenesis of TM IX (positions 324 to 351) was performed here to further investigate the functional significance of the domain. G328, S332, Q345, and L346 were newly identified as important for Na(+)-coupled proline uptake. Placement of Cys at one of these positions altered K(m(pro)) (S332C and L346C, 3- and 21-fold decreased, respectively; Q345C, 38-fold increased), K(0.5(Na+)) (S332C, 13-fold decreased; Q345C, 19-fold increased), and/or V(max) [G328C, S332C, Q345C, and L346C, 3-, 22-, 2-, and 8-fold decreased compared to PutP(wild type), respectively]. Membrane-permeant N-ethylmaleimide inhibited proline uptake into cells containing PutP with Cys at distinct positions in the middle (T341C) and cytoplasmic half of TM IX (C344, L347C, V348C, and S351C) and had little or no effect on all other single Cys PutP variants. The inhibition pattern was in agreement with the pattern of labeling with fluorescein-5-maleimide. In addition, Cys placed into the cytoplasmic half of TM IX (C344, L347C, V348C, and S351C) was protected from fluorescein-5-maleimide labeling by proline while Na(+) alone had no effect. Membrane-impermeant methanethiosulfonate ethyltrimethylammonium modified Cys in the middle (A337C and T341C) and periplasmic half (L331C) but not in the cytoplasmic half of TM IX in intact cells. Furthermore, Cys at the latter positions was partially protected by Na(+) but not by proline. Based on these results, a model is discussed according to which residues of TM IX participate in the formation of ligand-sensitive, hydrophilic cavities in the protein that may reconstitute part of the Na(+) and/or proline translocation pathway of PutP.

Role of Ser-340 and Thr-341 in transmembrane domain IX of the Na+/proline transporter PutP of Escherichia coli in ligand binding and transport

The Na+/solute symporter family comprises more than 400 members of pro- and eukaryotic origin. Using the Na+/proline transporter PutP of Escherichia coli as a model, the role of two conserved residues, Ser-340 and Thr-341, is investigated to obtain insights into the mechanism of transport catalyzed by members of this family. Substitution of these amino acids alters the transport kinetics of cells and proteoliposomes containing the PutP variants significantly. In particular, the apparent affinities for Na+ and Li+ are reduced by 2 orders of magnitude or more. Also proline binding is affected, albeit to a lesser extent than ion binding. Thereby, the presence of a hydroxyl group at position 341 is essential for high affinity ligand binding. Furthermore, Cys placed at position 340 or 341 reacts with sulfhydryl reagents of different polarity, indicating accessibility from the water phase. In addition, Cys cross-linking suggests proximity of the residues to other amino acids previously shown to be crucial for ligand binding. For these reasons it is suggested that Ser-340 and Thr-341 are located in a ligand translocation pathway. Furthermore, it is proposed that the side chain of Thr-341 directly participates in Na+ binding.

The importance of company: Na+ and Cl- influence substrate interaction with SLC6 transporters and other proteins

SLC6 transporters, which include transporters for gamma-aminobutyric acid (GABA), norepinephrine, dopamine, serotonin, glycine, taurine, L-proline, creatine, betaine, and neutral cationic amino acids, require Na+ and Cl- for their function, and this review covers the interaction between transporters of this family with Na+ and Cl- from a structure-function standpoint. Because detailed structure-function information regarding ion interactions with SLC6 transporters is limited, we cover other proteins cotransporting Na+ or Cl- with substrate (SLClA2, PutP, SLC5A1, melB), or ion binding to proteins in general (rhodanese, ATPase, LacY, thermolysine, angiotensin-converting enzyme, halorhodopsin, CFTR). Residues can be involved in directly binding Na+ or Cl-, in coupling ion binding to conformational changes in transporter, in coupling Na+ or Cl- movement to transport, or in conferring ion selectivity. Coordination of ions can involve a number of residues, and portions of the substrate and coupling ion binding sites can be distal in space in the tertiary structure of the transporter, with other portions that are close in space thought to be crucial for the coupling process. The reactivity with methanethiosulfonate reagents of cysteines placed in strategic positions in the transporter provides a readout for conformational changes upon ion or substrate binding. More work is needed to establish the relationships between ion interactions and oligomerization of SLC6 transporters.

Secondary transport of amino acids in prokaryotes

Amino acid transport is a ubiquitous phenomenon and serves a variety of functions in prokaryotes, including supply of carbon and nitrogen for catabolic and anabolic processes, pH homeostasis, osmoprotection, virulence, detoxification, signal transduction and generation of electrochemical ion gradients. Many of the participating proteins have eukaryotic relatives and are successfully used as model systems for exploration of transporter structure and function. Distribution, physiological roles, functional properties, and structure-function relationships of prokaryotic alpha-amino acid transporters are discussed.

State-dependent conformations of the translocation pathway in the tyrosine transporter Tyt1, a novel neurotransmitter:sodium symporter from Fusobacterium nucleatum

The gene of a novel prokaryotic member (Tyt1) of the neurotransmitter:sodium symporter (NSS) family has been cloned from Fusobacterium nucleatum. In contrast to eukaryotic and some prokaryotic NSSs, which contain 12 transmembrane domains (TMs), Tyt1 contains only 11 TMs, a characteristic shared by approximately 70% of prokaryotic NSS homologues. Nonetheless upon heterologous expression in an engineered Escherichia coli host, Tyt1 catalyzes robust Na+-dependent, highly selective l-tyrosine transport. Genetic engineering of Tyt1 variants devoid of cysteines or with individually retained endogenous cysteines at positions 18 or 238, at the cytoplasmic ends of TM1 and TM6, respectively, preserved normal transport activity. Whereas cysteine-less Tyt1 was resistant to the inhibitory effect of sulfhydryl-alkylating reagents, N-ethylmaleimide inhibited transport by Tyt1 variants containing either one or both of the endogenous cysteines, and this inhibition was altered by the substrates sodium and tyrosine, consistent with substrate-induced dynamics in the transport pathway. Our findings support a binding model of Tyt1 function in which an ordered sequence of substrate-induced structural changes reflects distinct conformational states of the transporter. This work identifies Tyt1 as the first functional bacterial NSS member putatively consisting of only 11 TMs and shows that Tyt1 is a suitable model for the study of NSS dynamics with relevance to structure/function relationships of human NSSs, including the dopamine, norepinephrine, serotonin, and gamma-aminobutyric acid transporters.

Functional analysis of conserved polar residues in Vc-NhaD, Na+/H+ antiporter of Vibrio cholerae

Vc-NhaD is a Na(+)/H(+) antiporter from Vibrio cholerae with a sharp maximum of activity at pH approximately 8.0. NhaD homologues are present in many bacteria as well as in higher plants. However, very little is known about structure-function relations in NhaD-type antiporters. In this work 14 conserved polar residues associated with putative transmembrane segments of Vc-NhaD have been screened for their possible role in the ion translocation and pH regulation of Vc-NhaD. Substitutions S150A, D154G, N155A, N189A, D199A, T201A, T202A, S389A, N394G, S428A, and S431A completely abolished the Vc-NhaD-mediated Na(+)-dependent H(+) transfer in inside-out membrane vesicles. Substitutions T157A and S428A caused a significant increase of apparent K(m) values for alkali cations, with the K(m) for Li(+) elevated more than that for Na(+), indicating that Thr-157 and Ser-428 are involved in alkali cation binding/translocation. Of six conserved His residues, mutation of only His-93 and His-210 affected the Na(+)(Li(+))/H(+) antiport, resulting in an acidic shift of its pH profile, whereas H93A also caused a 7-fold increase of apparent K(m) for Na(+) without affecting the K(m) for Li(+). These data suggest that side chains of His-93 and His-210 are involved in proton binding and that His-93 also contributes to the binding of Na ions during the catalytic cycle. These 15 residues are clustered in three distinct groups, two located at opposite sides of the membrane, presumably facilitating the access of substrate ions to the third group, a putative catalytic site in the middle of lipid bilayer. The distribution of these key residues in Vc-NhaD molecule also suggests that transmembrane segments IV, V, VI, X, XI, and XII are situated close to one another, creating a transmembrane relay of charged/polar residues involved in the attraction, coordination, and translocation of transported cations.

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.

CaiT of Escherichia coli, a new transporter catalyzing L-carnitine/gamma -butyrobetaine exchange

l-Carnitine is essential for beta-oxidation of fatty acids in mitochondria. Bacterial metabolic pathways are used for the production of this medically important compound. Here, we report the first detailed functional characterization of the caiT gene product, a putative transport protein whose function is required for l-carnitine conversion in Escherichia coli. The caiT gene was overexpressed in E. coli, and the gene product was purified by affinity chromatography and reconstituted into proteoliposomes. Functional analyses with intact cells and proteoliposomes demonstrated that CaiT is able to catalyze the exchange of l-carnitine for gamma-butyrobetaine, the excreted end product of l-carnitine conversion in E. coli, and related betaines. Electrochemical ion gradients did not significantly stimulate l-carnitine uptake. Analysis of l-carnitine counterflow yielded an apparent external K(m) of 105 microm and a turnover number of 5.5 s(-1). Contrary to related proteins, CaiT activity was not modulated by osmotic stress. l-Carnitine binding to CaiT increased the protein fluorescence and caused a red shift in the emission maximum, an observation explained by ligand-induced conformational alterations. The fluorescence effect was specific for betaine structures, for which the distance between trimethylammonium and carboxyl groups proved to be crucial for affinity. Taken together, the results suggest that CaiT functions as an exchanger (antiporter) for l-carnitine and gamma-butyrobetaine according to the substrate/product antiport principle.

The sodium/substrate symporter family: structural and functional features

Members of the sodium/substrate symporter family (SSSF, TC 2.A.21) catalyze the uptake of a wide variety of solutes including sugars, proline, pantothenate, and iodide into cells of pro- and eukaryotic origin. Extensive analyses of the topology of different SSSF proteins suggest an arrangement of 13 transmembrane domains as a common topological motif. Regions involved in sodium and/or substrate binding were identified. Furthermore, protein chemical and spectroscopic studies reveal ligand-induced structural alterations which are consistent with close interactions between the sites of sodium and substrate binding, thereby supporting an ordered binding mechanism for transport.

Employing Escherichia coli to functionally express, purify, and characterize a human transporter

Large-scale purification of recombinant human membrane proteins represents a rate-limiting step toward the understanding of their role in health and disease. There are only four mammalian membrane proteins of known structure, and these were isolated from natural sources (see http://www.mpibp-frankfurt.mpg.de/michel/public/memprotstruct.html). In addition, genetic diseases of membrane proteins are frequently caused by trafficking defects, and it is enigmatic whether these mutants are functional. Here, we report the employment of Escherichia coli for the functional expression, purification, and reconstitution of a human membrane protein, the human Na+/glucose cotransporter (hSGLT1). The use of an E. coli mutant defective in the outer membrane protease OmpT, incubation temperatures below 20 degrees C, and transcriptional regulation from the lac promoter/operator are crucial to reduce proteolytic degradation. Purification of a recombinant hSGLT1 through affinity chromatography yields about 1 mg of purified recombinant hSGLT1 per 3 liters of cultured bacterial cells. Kinetic analysis of hSGLT1 in proteoliposomes reveals that a purified recombinant transporter, which is missorted in eukaryotic cells, retains full catalytic activity. These results indicate the power of bacteria to manufacture and isolate human membrane proteins implicated in genetic diseases.

Sites important for Na+ and substrate binding in the Na+/proline transporter of Escherichia coli, a member of the Na+/solute symporter family

To elucidate the functional importance of transmembrane domain II in the Na(+)/proline transporter (PutP) of Escherichia coli we analyzed the effect of replacing Ser-54 through Gly-58. Substitution of Asp-55 or Met-56 dramatically reduces the apparent affinity for Na(+) and Li(+) in a cation-dependent manner. Conversely, Cys in place of Gly-58 significantly reduces only the apparent proline affinity while substitution of Ser-57 results in a dramatic reduction of the apparent proline and cation affinities. Interestingly, upon increasing the proline concentration the apparent Na(+) affinity of Ser-57 replacement mutants converges toward the wild-type value, indicating a close cooperativity between cation and substrate site(s). This notion is supported by the fact that Na(+)-stimulated site-specific fluorescence labeling of a single Cys at position 57 is completely reversed by the addition of proline. Similar results are obtained upon labeling of a Cys at position 54 or 58. Taken together, these results indicate that Asp-55 and Met-56 are located at or close to the ion-binding site while Ser-54, Ser-57, and Gly-58 may be close to the proline translocation pathway. In addition, the data prod at an involvement of the latter residues in ligand-induced conformational dynamics that are crucial for cation-coupled transport.

Trans membrane domain IV is involved in ion transport activity and pH regulation of the NhaA-Na(+)/H(+) antiporter of Escherichia coli

We have previously shown that the activity of NhaA is regulated by pH and found mutations that affect dramatically the pH dependence of the rate but not the K(m) (for Na(+) and Li(+)) of NhaA. In the present work, we found that helix IV is involved both in ion translocation as well as in pH regulation of NhaA. Two novel types of NhaA mutants were found clustered in trans membrane segment (TMS) IV: One type (D133C, T132C, and P129L) affects the apparent K(m) of NhaA to the cations with no significant effect on the pH profile of the antiporter; no shift of the pH profile was found when the activity of these mutants was measured at saturating Na(+) concentration. In contrast, the other type of mutations (A127V and A127T) was found to affect both the K(m) and the pH dependence of the rate of NhaA whether tested at saturating Na(+) concentration or not. These results imply that residues involved in the ion translocation of NhaA may (A127) or may not (D133, T132, and P129) overlap with those affecting the pH response of the antiporter. All mutants cluster in the N-terminal half of the putative alpha-helix IV, one type on one face, the other on the opposite. Cys accessibility test demonstrated that although D133C is located in the middle of TMS IV, it is inhibited by N-ethylmaleimide and is exposed to the cytoplasm.

Towards the molecular mechanism of Na(+)/solute symport in prokaryotes

The Na(+)/solute symporter family (SSF, TC No. 2.A.21) contains more than 40 members of pro- and eukaryotic origin. Besides their sequence similarity, the transporters share the capability to utilize the free energy stored in electrochemical Na(+) gradients for the accumulation of solutes. As part of catabolic pathways most of the transporters are most probably involved in the acquisition of nutrients. Some transporters play a role in osmoadaptation. With a high resolution structure still missing, a combination of genetic, protein chemical and spectroscopic methods has been used to gain new insights into the structure and molecular mechanism of action of the transport proteins. The studies suggest a common 13-helix motif for all members of the SSF according to which the N-terminus is located in the periplasm and the C-terminus is directed into the cytoplasm (except for proteins containing a N- or C-terminal extension). Furthermore, an amino acid substitution analysis of the Na(+)/proline transporter (PutP) of Escherichia coli, a member of the SSF, has identified regions of particular functional importance. For example, amino acids of TM II of PutP proved to be critical for high affinity binding of Na(+) and proline. In addition, it was shown that ligand binding induces widespread conformational alterations in the transport protein. Taken together, the studies substantiate the common idea that Na(+)/solute symport is the result of a series of ligand-induced structural changes.

Sodium-substrate cotransport in bacteria

A variety of sodium-substrate cotransport systems are known in bacteria. Sodium enters the cell down an electrochemical concentration gradient. There is obligatory coupling between the entry of the ion and the entry of substrate with a stoichiometry (in the cases studied) of 1:1. Thus, the downhill movement of sodium ion into the cell leads to the accumulation of substrate within the cell. The melibiose carrier of Escherichia coli is perhaps the most carefully studied of the sodium cotransport systems in bacteria. This carrier is of special interest because it can also use protons or lithium ions for cotransport. Other sodium cotransport carriers that have been studied recently are for proline, glutamate, serine-threonine, citrate and branched chain amino acids.

Characterization of the Vibrio parahaemolyticus Na+/Glucose cotransporter. A bacterial member of the sodium/glucose transporter (SGLT) family

The Vibrio parahaemolyticus sodium/glucose transporter (vSGLT) is a bacterial member of the SGLT gene family. Wild-type and mutant vSGLT proteins were expressed in Escherichia coli, and transport activity was measured in intact cells and plasma membrane vesicles. Two cysteine-less vSGLT proteins exhibited sugar transport rates comparable with that of the wild-type protein. Six residues in two regions of vSGLT known to be of functional importance in SGLT1 were replaced individually with cysteine in the cysteine-less protein. Characterization of these single cysteine-substituted vSGLTs showed that two residues (Gly-151 and Gln-428) are essential for transport function, whereas the other four residues (Leu-147, Leu-149, Ala-423, and Gln-425) are not. 2-Aminoethylmethanethiosulfonate (MTSEA) blocked Na(+)/glucose transport by only the transporter bearing a cysteine at position 425 (Q425C). MTSEA inhibition was reversed by dithiothreitol and blocked by the presence of both Na(+) and d-glucose, indicating that conformational changes of the vSGLT protein are involved in Na(+)/glucose transport. A split version of vSGLT was generated by co-expression of the N-terminal (N(7)) and C-terminal (C(7)) halves of the transporter. The split vSGLT maintained Na(+)-dependent glucose transport activity. Chemical cross-linking of split vSGLT, with a cysteine in each N(7) and C(7) fragment, suggested that hydrophilic loops between helices 4 and 5 and between helices 10 and 11 are within 8 A of each other. We conclude that the mechanism of Na(+)/glucose transport by vSGLT is similar to mammalian SGLTs and that further studies on vSGLT will provide novel insight to the structure and function of this class of cotransporters.

Spin labeling analysis of structure and dynamics of the Na(+)/proline transporter of Escherichia coli

With respect to the functional importance attributed to the N-terminal part of the Na(+)/proline transporter of Escherichia coli (PutP), we report here on the structural arrangement and functional dynamics of transmembrane domains (TMs) II and III and the adjoining loop regions. Information on membrane topography was obtained by analyzing the residual mobility of site-specifically-attached nitroxide spin label and by determination of collision frequencies of the nitroxide with oxygen and a polar metal ion complex using electron paramagnetic resonance (EPR) spectroscopy. The studies suggest that amino acids Phe45, Ser50, Ser54, Trp59, and Met62 are part of TM II while Gly39 and Arg40 are located at a membrane-water interface probably forming the cytoplasmic cap of the TM. Also Ala67 and Glu75 are at a membrane-water interface, suggesting a location close to the periplasmic ends of TMs II and III, respectively. Ser71 between these residues is clearly in a water-exposed loop (periplasmic loop 3). Spin labels attached to positions 80, 86, and 91 show EPR properties typical for a TM location (TM III). Leu97 may be part of a structured loop region while Ala107 is clearly located in a water-exposed loop (cytoplasmic loop 4). Finally, spin labels attached to the positions of Asp33 and Leu37 are clearly on the surface of the transporter and are directed into an apolar environment. These findings strongly support the recently proposed 13-helix model of PutP [Jung, H., Rübenhagen, R., Tebbe, S., Leifker, K., Tholema, N., Quick, M., and Schmid, R. (1998) J. Biol. Chem. 273, 26400-26407] and suggest that TMs II and III of the transporter are formed by amino acids Ser41 to Gly66 and Ser76 to Gly95, respectively. In addition to the topology analysis, it is shown that binding of Na(+) and/or proline to the transporter alters the mobility of the nitroxide group at the positions of Leu37 and Phe45. From these findings, it is concluded that binding of the ligands induces conformational alterations of PutP that involve at least parts of TM II and the preceding cytoplasmic loop.

Role of conserved Arg40 and Arg117 in the Na+/proline transporter of Escherichia coli

The Na+/proline transporter of Escherichia coli (PutP) is a member of a large family of Na+/solute symporters. To investigate the role of Arg residues which are conserved within this family, Arg40 at the cytoplasmic end of transmembrane domain (TM) II and Arg117 in cytoplasmic loop 4 of PutP are subjected to amino acid substitution analysis. Removal of the positive charge at position 40 (PutP-R40C, Q, E) leads to a dramatic decrease of the V(max) of Na(+)-coupled proline uptake (1-10% of PutP-wild-type). The reduced transport rates are accompanied by decreased apparent affinities of the transporter for Na+ and Li+ while the apparent affinity for proline is only slightly altered. Furthermore, single Cys PutP-R40C reacts with N-ethylmaleimide (NEM), and this reaction is partially inhibited by proline and more efficiently by Na+ ions. Remarkably, NEM modification of Cys40 inhibits Na(+)-driven proline uptake almost completely while facilitated influx of proline into deenergized cells is stimulated by this reaction, suggesting an at least partially uncoupled phenotype under these conditions. These results suggest that Arg40 is located close to the site of ion binding and is important for the coupling of ion and proline transport. The observations confirm the functional importance of TM II described in earlier studies [M. Quick and H. Jung (1997) Biochemistry 36, 4631-4636]. In contrast to Arg40, Arg117 is apparently not important for function of the mature protein. The low transport rates observed upon substitution of Arg117 (PutP-R117C, K, Q) can at least partially be attributed to reduced amounts of PutP in the membrane. However, once inserted into the membrane, PutP containing Arg117 replacements shows a stability comparable to the wild-type as indicated by pulse-chase experiments. These observations suggest that Arg117 plays a crucial role at a stage prior to complete functional insertion of PutP into the membrane, i. e., by stabilizing a folding intermediate.

Change to alanine of one out of four selectivity filter glycines in KtrB causes a two orders of magnitude decrease in the affinities for both K+ and Na+ of the Na+ dependent K+ uptake system KtrAB from Vibrio alginolyticus

KtrAB from Vibrio alginolyticus is a recently described new type of high affinity bacterial K+ uptake system. Its activity assayed in an Escherichia coli K+ uptake negative mutant depended on Na+ ions (Km of 40 microM). Subunit KtrB contains four putative P-loops. The selectivity filter from each P-loop contains a conserved glycine residue. Residue Gly-290 from the third P-loop selectivity filter in KtrB was exchanged for Ala, Ser or Asp. KtrB variants Ser-290 and Asp-290 were without activity. In contrast, KtrB variant Ala-290 was still active. This variant transported K+ with a two orders of magnitude decrease in apparent affinity for both K+ and Na+ with little effect on Vmax.

Topology of the Na+/proline transporter of Escherichia coli

Hydropathy profile analysis of the amino acid sequence of the Na+/proline transporter of Escherichia coli (PutP) suggests that the protein consists of 12 transmembrane domains (TMs) which are connected by hydrophilic loops (Nakao, T., Yamato, I., and Anraku, Y. (1987) Mol. Gen. Genet. 208, 70-75). We have tested this prediction by applying a gene fusion approach in combination with a Cys accessibility analysis and site-specific proteolysis. Characterization of a series of PutP-alkaline phosphatase (PhoA) and PutP-beta-galactosidase (LacZ) hybrid proteins yields a reciprocal activity pattern of the reporter proteins that is in agreement with the topology of TMs III to XII of the 12-helix model. Placement of the PutP-PhoA and PutP-LacZ junction sites closer to the N terminus does not yield conclusive results. As a prerequisite for further topology studies, a functional PutP molecule devoid of all five native Cys residues (Cys-free PutP) is generated. Subsequently, amino acids in Cys-free PutP are replaced individually with Cys, and the accessibility of the sulfhydryl groups is analyzed. Surprisingly, Cys residues placed close to the N terminus of PutP (Ile-3 --> Cys, Thr-5 --> Cys) or into putative TM II (Ser-71 --> Cys, Glu-75 --> Cys) are highly accessible to membrane permeant and impermeant thiol reagents in intact cells. In contrast, Cys at the C terminus (Ser-502 --> Cys) reacts only with the membrane permeant but not with the impermeant reagent in intact cells. These results contradict the 12-helix motif and indicate a periplasmic location of the N terminus whereas the C terminus faces the cytoplasm. In addition, a transporter with Cys in place of Leu-37 (putative periplasmic loop (pL2) shows the same accessibility pattern as the Cys at the C terminus. Furthermore, PutP which has been purified and reconstituted into proteoliposomes in an inside-out orientation, is readily cleaved by the endoproteinase AspN before Asp-33 (pL2), Asp-112 (putative cytoplasmic loop (cL3), Asp-262 (cL7), and Asp-356 (cL9). These results suggest a cytosolic location of Asp-33 and Leu-37, thereby implying the formation of an additional TM formed by amino acids of pL2. Based on these observations, a new secondary structure model is proposed according to which the protein consists of 13 TMs with the N terminus on the outside and the C terminus facing the cytoplasm. The 13-helix structure is discussed as a common topological motif for all members of the Na+/solute cotransporter family.

A conserved aspartate residue, Asp187, is important for Na+-dependent proline binding and transport by the Na+/proline transporter of Escherichia coli

Asp187 in the Na+/proline transporter of Escherichia coli (PutP) is conserved within the Na+/solute cotransporter family. Information on the role of this residue has been gained by amino acid substitution analysis. PutP with Glu, Asn, or Cys in place of Asp187 catalyzed Na+-coupled proline uptake at 75%, 25%, and 1.5%, respectively, of the Vmax of PutP-wild-type while the apparent Km for proline was only slightly altered. Importantly, acetylation or amidoacetylation of an engineered transporter containing a single Cys at position 187 stimulated proline uptake. Strikingly, PutP-D187C exhibited high-affinity proline binding even at very low Na+ concentrations (2 microM) while proline binding to PutP-wild-type, -D187E, and -D187N was strictly dependent on the Na+ concentration. The apparent independence of proline binding from the Na+ concentration can at least partially be attributed to an enhanced Na+ affinity of PutP-D187C. In addition, reaction of PutP containing a single Cys at position 187 with N-ethylmaleimide was inhibited by Na+ but not by Li+ or proline. The results indicate that electrostatic interactions of the amino acid side chain at position 187 in PutP with other parts of the transporter and/or the coupling ion are crucial for active proline transport. It is suggested that Asp187 is located close to the pathway of the coupling ion through the membrane and may be involved in the release of Na+ on the cytoplasmic side of the membrane.

Unidirectional reconstitution and characterization of purified Na+/proline transporter of Escherichia coli

A simple approach for large-scale purification and unidirectional reconstitution of the Na+/proline transporter of Escherichia coli (PutP) is described. The procedure is based on the insertion of a highly polar peptide composed of 17 amino acids including a 6His tag at the C-terminus of the transporter. Purification of the hybrid protein is achieved by Ni+-NTA affinity (purity >95%) and ion exchange chromatography (purity >99%). The purified transporter is reconstituted into preformed, detergent-destabilized liposomes. Detergent is removed slowly by adsorption to polystyrene beads. The highest activities [Vmax = 1.1 x 10(3) nmol min-1 (mg of protein)-1] are measured when Triton X100 is used for liposomes destabilization at a concentration corresponding to the onset of lipid solubilization. Site-directed labeling of PutP and site-specific proteolytic cleavage indicate that the transporter is inserted into proteoliposomes in an inside-out orientation. Reconstituted PutP is able to accumulate proline against a concentration gradient in the presence of an inwardly directed electrochemical Na+ or Li+ gradient, while a pH gradient does not affect transport. The apparent proline affinity of PutP in proteoliposomes is similar to the value determined with intact cells. Interestingly however, the apparent Na+ affinity of reconstituted PutP is reduced by a factor of about 25 compared to cells, suggesting a lower cation affinity on the cytosolic side of PutP relative to the outside.

Topology and function of the Na+/proline transporter of Escherichia coli, a member of the Na+/solute cotransporter family

The Na+/proline transporter of Escherichia coli (PutP) is a member of the Na+/solute contransporter family (SCF) and catalyzes the uptake of proline by a Na+ dependent transport mechanism. Hydropathy profile analysis suggests that the protein consists of 12 transmembrane domains (TMs) that traverse the membrane in zigzag fashion connected by hydrophilic loops. However, analysis of a series of putP-phoA (PutP-alkaline phosphatase) and putP-lacZ (PutP-beta-galactosidase) fusions and site-directed labeling of the transporter indicate a 13-helix motif with the N-terminus on the outside and the C-terminus facing the cytoplasm. The findings are discussed with respect to a common topological motif for all members of the SCF. Furthermore, amino acid substitution analysis indicates that the N-terminal part of PutP is important for ion binding. Thus, Asp55 (putative TM II) is essential for transport and proposed to interact directly with Na+. The functional importance of TM II is further confirmed by the observation that replacement of Arg40, Ser50, Ala53, or Ser57 alters transport kinetics dramatically.

Aspartate 55 in the Na+/proline permease of Escherichia coli is essential for Na+-coupled proline uptake

Four acidic residues in the N-terminal domain of Na+/proline permease of Escherichia coli (Asp33, Asp34, and Asp55 in putative loop 2, Glu75 in putative transmembrane domain II) were individually replaced with neutral or charged amino acid residues. Replacement of Glu75, the only residue in the permease presumed to be in the middle of a transmembrane domain, Asp33, or Asp34 had little or no influence on the kinetics of Na+-coupled proline transport. In contrast, removal of the carboxylate at position 55 (Asp55 --> Asn or Asp55 --> Cys permease) impaired proline uptake completely while lengthening of the side chain at this position by one methylene group (Asp55 --> Glu permease) allowed transport at a reduced initial rate. Importantly, all permease molecules were present in the membrane at concentrations comparable to the wild-type protein. Kinetic analysis of Na+-coupled proline transport catalyzed by Asp55 --> Glu permease revealed a 5-fold increase of the K(m) for proline and a 30-fold decrease of the V(max) compared to wild-type. Remarkably, replacement of Asp55 by Glu led to a 50-fold decrease of the apparent affinity of the permease for Na+. Furthermore, replacement of Asp55 with Cys or Asn blocked proline-induced Na+ uptake whereas significant Na+ transport was observed with Asp55 --> Glu permease. In addition, transport of proline down its concentration gradient was not detectable with deenergized cells containing Asp55 --> Glu permease at low Na+ concentrations. However, downhill transport activity was observed in the presence of high Na+ concentrations. Replacement of Asp55 with Asn or Cys impaired downhill transport under all conditions tested. The observations demonstrate that a carboxylate at position 55 of proline permease is essential for Na+-coupled proline transport. It is suggested that Asp55 may be involved in binding of the coupling ion.