Modulation of ATPase activity by physical disengagement of the ATP-binding domains of an ABC transporter, the histidine permease.

The membrane-bound complex of the prokaryotic histidine permease, a periplasmic protein-dependent ABC transporter, is composed of two hydrophobic subunits, HisQ and HisM, and two identical ATP-binding subunits, HisP, and is energized by ATP hydrolysis. The soluble periplasmic binding protein, HisJ, creates a signal that induces ATP hydrolysis by HisP. The crystal structure of HisP has been resolved and shown to have an "L" shape, with one of its arms (arm I) being involved in ATP binding and the other one (arm II) being proposed to interact with the hydrophobic subunits (Hung, L.-W., Wang, I. X., Nikaido, K., Liu, P.-Q., Ames, G. F.-L., and Kim, S.-H. (1998) Nature 396, 703-707). Here we study the basis for the defect of several HisP mutants that have an altered signaling pathway and hydrolyze ATP constitutively. We use biochemical approaches to show that they produce a loosely assembled membrane complex, in which the mutant HisP subunits are disengaged from HisQ and HisM, suggesting that the residues involved are important in the interaction between HisP and the hydrophobic subunits. In addition, the mutant HisPs are shown to have lower affinity for ADP and to display no cooperativity for ATP. All of the residues affected in these HisP mutants are located in arm II of the crystal structure of HisP, thus supporting the proposed function of arm II of HisP as interacting with HisQ and HisM. A revised model involving a cycle of disengagement and reengagement of HisP is proposed as a general mechanism of action for ABC transporters.     

Reconstitution of the histidine periplasmic transport system in membrane vesicles. Energy coupling and interaction between the binding protein and the membrane complex

The periplasmic histidine transport system of Salmonella typhimurium has been reconstituted in isolated right-side-out membrane vesicles. The reconstituted system is entirely dependent on both the periplasmic protein, HisJ, and the membrane-bound complex, composed of proteins HisQ, HisM, and HisP. Transport is also dependent on the presence of ascorbate and phenazine methosulfate, which provide the energy for transport. Ascorbate oxidation generates a proton-motive-force, which allows ATP synthesis. ATP (or a cogenerated molecule) appears to be the immediate energy donor. Dissipation of the proton-motive-force or reduction of the level of ATP by a variety of treatments results in inhibition of transport. Vanadate inhibits transport, indicating that ATP utilization is necessary to energize transport. The interaction between liganded HisJ and the membrane complex has been measured directly: it displays Michaelis-Menten type kinetics, with a K1/2 of approximately 65 microM. The significance of this finding in terms of transport properties of whole cells is discussed.     

Topology of the hydrophobic membrane-bound components of the histidine periplasmic permease. Comparison with other members of the family.

The membrane-bound complex of periplasmic permeases comprises two hydrophobic proteins which have been hypothesized to be integral membrane-spaninning proteins. We have investigated the topological organization of the hydrophobic components of the Salmonella typhimurium histidine permease, HisQ and HisM. Both proteins are digested by trypsin and proteinase K when either inside-out or right-side-out membrane vesicles are used. Therefore, these proteins are exposed to both surfaces of the membrane. Digestion with carboxypeptidase and binding studies with antibodies directed against the carboxyl terminus of HisQ and HisM have localized their carboxyl termini to the inside surface of the cytoplasmic membrane. Aminopeptidase digestion suggests periplasmic localization of their amino termini. Alkaline phosphatase fusions to HisQ and HisM indicate the existence of five spanners in both proteins. The periodicity and orientation of spanners and loops in HisQ and HisM match those of the five carboxyl-terminal spanners of MalF, the only other hydrophobic component of the periplasmic permeases for which topological information is available. An alignment of the sequences of all known hydrophobic components of periplasmic permeases is presented which indicates clear conservation of secondary structure and some conservation of primary sequence. The structural conservation of the components is discussed, and a role for a hydrophilic loop containing a conserved sequence (the EAA loop) is proposed.     

One intact ATP-binding subunit is sufficient to support ATP hydrolysis and translocation in an ABC transporter, the histidine permease.

The membrane-bound complex of the Salmonella typhimurium histidine permease, a member of the ABC transporters (or traffic ATPases) superfamily, is composed of two integral membrane proteins, HisQ and HisM, and two copies of an ATP-binding subunit, HisP, which hydrolyze ATP, thus supplying the energy for translocation. The three-dimensional structure of HisP has been resolved. Extensive evidence indicates that the HisP subunits form a dimer. We investigated the mechanism of action of such a dimer, both within the complex and in soluble form, by creating heterodimers between the wild type and mutant HisP proteins. The data strongly suggest that within the complex both subunits hydrolyze ATP and that one subunit is activated by the other. In a heterodimer containing one wild type and one hydrolysis defective subunit both hydrolysis and ligand translocation occur at half the rate of the wild type. Soluble HisP also hydrolyzes ATP if one subunit is inactive; its specific activity is identical to that of the wild type, indicating that only one of the subunits in a soluble dimer is involved in hydrolysis. We show that the activating ability varies depending on the nature of the substitution of a well conserved residue, His-211.     

Reconstitution of periplasmic transport in inside-out membrane vesicles. Energization by ATP

The periplasmic histidine permease of Salmonella typhimurium has been reconstituted in inside-out vesicles (IOV) of Escherichia coli by disrupting the cells with a French press in the presence of a high concentration of the periplasmic histidine-binding protein, HisJ. Efflux from IOV, which is equivalent to uptake in whole cells, is induced by ATP. The reconstituted system depends on the presence of the membrane-bound permease proteins, HisQ, HisM, and HisP, and does not function if reconstitution is performed in the presence of a mutant HisJ protein, HisJ5625, that can bind histidine normally but can't interact properly with the membrane complex. Efflux is not induced by the nonhydrolyzable ATP analog, adenyl-5'-yl imidodiphosphate, supporting the contention that ATP hydrolysis is necessary. 8-Azido ATP inactivates IOV, indicating that the ATP effect occurs through the HisP protein, which has previously been shown to be modified by 8-azido ATP (Hobson, A., Weatherwax, R., and Ames, G.F.-L. (1984) Proc. Natl. Acad. Sci. U. S. A. 81, 733-7337). The estimated Km of the vesicles for ATP is about 200 microM. Vanadate, an inhibitor of phosphohydrolase enzymes, inhibits ATP-induced efflux. We conclude that ATP is likely to be the proximal energy source for periplasmic permeases.     

Nonequivalence of the nucleotide-binding subunits of an ABC transporter, the histidine permease, and conformational changes in the membrane complex

The membrane-bound complex of the Salmonella typhimurium histidine permease, an ABC transporter (or traffic ATPase), is composed of two membrane proteins, HisQ and HisM, and two identical copies of an ATP-hydrolyzing protein, HisP. We have developed a technique that monitors quantitatively the sulfhydryl modification levels within the intact complex, and we have used it to investigate whether the HisP subunits behave identically within the complex. We show here that they interact differently with various thiol-specific reagents, thus indicating that, despite being identical, they are arranged asymmetrically. The possible basis of this asymmetry is discussed. We have also analyzed the occurrence of conformational changes during various stages of the activity cycle using thiol-specific reagents, fluorescence measurements, and circular dichroism spectroscopy. Cys-51, located close to the ATP-binding pocket, reflects conformational changes upon binding of ATP but does not participate in changes involved in signaling and translocation. The latter are shown to cause secondary structure alterations, as indicated by changes in alpha-helices; tertiary structure alterations also occur, as shown by fluorescence studies.     

Purification and Characterization of the Membrane-Bound Complex of an ABC Transporter, the Histidine Permease

The bacterial histidine permease, an ABC transporter, from Salmonella typhimurium is composed of a membrane-bound complex, HisQMP2, comprising two hydrophobic subunits (HisQ and HisM), two copies of an ATP-hydrolyzing subunit, HisP, and a soluble receptor, HisJ. We describe the purification and characterization of HisQMP2 using a 6-histidines extension at the carboxy terminus of HisP [HisQMP2(his6)]. The purification is rapid and effective, giving a seven-fold purification with a yield of 85 and 98% purity. Two procedures are described differing in the detergent used (decanoylsucrose and octylglucoside, respectively) and in the presence of phospholipid. HisQMP2(his6) has ATPase and transport activities upon reconstitution into proteoliposomes (PLS). HisQMP2(his6) has a low level ATPase activity (intrinsic activity), which is stimulated to a different extent by the receptor--liganded and unliganded. Its pH optimum is 7.8-8.0, it requires a cation for activity and it displays cooperativity for ATP. The effect of various ATP analogs was analyzed. Determination of the molecular size of HisQMP2(his6) indicates that it is a monomer. The permeability properties of two kinds of reconstituted PLS preparations are described.     

The nucleotide-binding site of HisP, a membrane protein of the histidine permease. Identification of amino acid residues photoaffinity labeled by 8-azido-ATP

The periplasmic histidine transport system (permease) of Escherichia coli and Salmonella typhimurium is composed of a soluble, histidine-binding receptor located in the periplasm and a complex of three membrane-bound proteins of which one, HisP, was shown previously to bind ATP. These permeases are energized by ATP. HisP is a member of a family of membrane transport proteins which is conserved in all periplasmic permeases and is presumed to be involved in coupling the energy of ATP to periplasmic transport. In this paper the nature of the ATP-binding site of HisP has been explored by identification of some of the residues that come into contact with ATP. HisP was derivatized with 8-azido-ATP (N3ATP). Both the underivatized and the derivatized forms of HisP were solubilized, purified, and digested with trypsin. The resulting tryptic peptides were resolved by high pressure liquid chromatography, and peptides modified by N3ATP were isolated and sequenced. Two peptides, X and Z, spanning amino acid residues 16-23 and 31-45, were found to contain sites of N3ATP attachment at His19 and Ser41, respectively. Both peptides are close to the amino-terminal end of HisP; peptide Z is located in one of the well conserved regions comprising the nucleotide-binding consensus motifs of the energy-coupling components of these permeases. These consensus motifs are found in many purine nucleotide-binding proteins. The relationship between the location of these residues and the overall structure of the ATP-binding site is discussed.     

Salmonella typhimurium histidine periplasmic permease mutations that allow transport in the absence of histidine-binding proteins.

Periplasmic transport systems consist of a membrane-bound complex and a periplasmic substrate-binding protein and are postulated to function by translocating the substrate either through a nonspecific pore or through specific binding sites located in the membrane complex. We have isolated mutants carrying mutations in one of the membrane-bound components of the histidine permease of Salmonella typhimurium that allow transport in the absence of both histidine-binding proteins HisJ and LAO (lysine-, arginine-, ornithine-binding protein). All of the mutations are located in a limited region of the nucleotide-binding component of the histidine permease, HisP. The mutants transported substrate in the absence of binding proteins only when the membrane-bound complex was produced in large amounts. At low (chromosomal) levels, the mutant complex was unable to transport substrate in the absence of binding proteins but transported it efficiently in the presence of HisJ. The alterations responsible for the mutations were identified by DNA sequencing; they are closely related to a group of hisP mutations isolated as suppressors of HisJ interaction mutations (G. F.-L. Ames and E. N. Spudich, Proc. Natl. Acad. Sci. USA 73:1877-1881, 1976). The hisP suppressor mutations behaved similarly to these newly isolated mutations despite the entirely different selection procedure. The results are consistent with the HisP protein carrying or contributing to the existence of a substrate-binding site that can be mutated to function in the absence of a binding protein.     

Structure and mechanism of bacterial periplasmic transport systems

Bacterial periplasmic transport systems are complex, multicomponent permeases, present in Gram-negative bacteria. Many such permeases have been analyzed to various levels of detail. A generalized picture has emerged indicating that their overall structure consists of four proteins, one of which is a soluble periplasmic protein that binds the substrate and the other three are membrane bound. The liganded periplasmic protein interacts with the membrane components, which presumably form a complex, and which by a series of conformational changes allow the formation of an entry pathway for the substrate. The two extreme alternatives for such pathway involve either the formation of a nonspecific hydrophilic pore or the development of a ligand-binding site(s) on the membrane-bound complex. One of the membrane-bound components from each system constitutes a family of highly homologous proteins containing sequence domains characteristic of nucleotide-binding sites. Indeed, in several cases, they have been shown to bind ATP, which is thus postulated to be involved in the energy-coupling mechanism. Interestingly, eukaryotic proteins homologous to this family of proteins have been identified (mammalianmdr genes and Drosophilawhite locus), thus indicating that they perform a universal function, presumably related to energy coupling in membrane-related processes. The mechanism of energy coupling in periplasmic permeases is discussed.     

Bacterial periplasmic permeases belong to a family of transport proteins operating from Escherichia coli to human: Traffic ATPases

Bacterial periplasmic transport systems are complex permeases composed of a soluble substrate-binding receptor and a membrane-bound complex containing 2-4 proteins. Recent developments have clearly demonstrated that these permeases are energized by the hydrolysis of ATP. Several in vitro systems have allowed a detailed study of the essential parameters functioning in these permeases. Several of the component proteins have been shown to interact with each other and the actual substrate for the transport process has been shown to be the liganded soluble receptor. The affinity of this substrate for the membrane complex is approximately 10 microM. The involvement of ATP in energy coupling is mediated by one of the proteins in the membrane complex. For each specific permease, this protein is a member of a family of conserved proteins which bind ATP. The similarity between the members of this family is high and extends itself beyond the consensus motifs for ATP binding. Interestingly, over the last few years, several eukaryotic membrane-bound proteins have been discovered which bear a high level of homology to the family of the conserved components of bacterial periplasmic permeases. Most of these proteins are known to, or can be inferred to participate in a transport process, such as in the case of the multidrug resistance protein (MDR), the STE6 gene product of yeast, and possibly the cystic fibrosis protein. This homology suggests a similarity in the mechanism of action and possibly a common evolutionary origin. This exciting development will stimulate progress in both the prokaryotic and eukaryotic areas of research by the use of overlapping procedures and model building. We propose that this universal class of permeases be called 'Traffic ATPases' to distinguish them from other types of transport systems, and to highlight their involvement in the transport of a vast variety of substrates in either direction relative to the cell interior and their use of ATP as energy source.     

Binding protein-independent histidine permease mutants. Uncoupling of ATP hydrolysis from transmembrane signaling

Periplasmic permeases consist of a substrate-binding receptor, located in the periplasm, and a membrane-bound complex composed of two integral membrane proteins and two nucleotide-binding proteins. The receptor interacts with the membrane-bound complex, which, upon receiving this signal, is postulated to hydrolyze ATP and translocate the substrate. We show that a class of mutations in the membrane-bound complex of the histidine permease, which allow transport in the absence of the substrate-binding protein, hydrolyze ATP independently from any signal. The data are compatible with the notion that cross-membrane signaling between the liganded periplasmic receptor and the cytoplasmic ATP-binding sites initiates conformational changes leading to ATP hydrolysis and substrate translocation.     

Crystal structure of the lysine-, arginine-, ornithine-binding protein (LAO) from Salmonella typhimurium at 2.7-A resolution.

A wide variety of sugars, amino acids, peptides, and inorganic ions are transported into bacteria by periplasmic transport systems consisting of substrate-specific receptors (binding proteins) and membrane-bound protein complexes. The crystal structure of the lysine-, arginine-, ornithine-binding protein (LAO) at 2.7-A resolution shows that the molecule has a bi-lobal structure and that its topological structure is different from other amino acid-binding proteins but is similar to the sulfate-binding protein and maltose-binding protein. High sequence homology between LAO and the histidine-binding protein (HisJ) and the fact that LAO and HisJ share the same membrane-bound protein complex allow one to define functional regions responsible for the ligand binding and for the interaction with the membrane complex.     

Characterization of lipopolysaccharide transport protein complex

Lipopolysaccharide (LPS) is an essential component of the outer membranes (OM) of most Gram-negative bacteria, which plays a crucial role in protection of the bacteria from toxic compounds and harsh conditions. The LPS is biosynthesized at the cytoplasmic side of inner membrane (IM), and then transported across the aqueous periplasmic compartment and assembled correctly at the outer membrane. This process is accomplished by seven LPS transport proteins (LptA-G), but the transport mechanism remains poorly understood. Here, we present findings by pull down assays in which the periplasmic component LptA interacts with both the IM complex LptBFGC and the OM complex LptDE in vitro, but not with complex LptBFG. Using purified Lpt proteins, we have successfully reconstituted the seven transport proteins as a complex in vitro. In addition, the LptC may play an essential role in regulating the conformation of LptBFG to secure the lipopolysaccharide from the inner membrane. Our results contribute to the understanding of lipopolysaccharide transport mechanism and will provide a platform to study the detailed mechanism of the LPS transport in vitro.     

Characterization of the NapGH quinol dehydrogenase complex involved in Wolinella succinogenes nitrate respiration

Nitrate respiration catalysed by the ε-proteobacterium Wolinella succinogenes relies on the NapAGHBFLD system that comprises periplasmic nitrate reductase (NapA) and various other Nap proteins required for electron transport from menaquinol to NapA or maturation of Nap components. The W. succinogenes Nap system is unusual as electron transfer to NapA was shown previously to depend on both subunits of the predicted menaquinol dehydrogenase complex NapGH but did not require a cytochrome c of the NapC/NrfH family. Nonetheless, minor residual growth by nitrate respiration was observed in napG and napH gene inactivation mutants. Here, the question is addressed whether alternative membrane-bound menaquinol dehydrogenases, like NrfH and NosGH, involved in nitrite or N₂O reduction systems, are able to functionally replace NapGH. The phenotypes of various gene deletion mutants as well as strains expressing chimeric nap / nos operons demonstrate that NosH is able to donate electrons to the respiratory chain of nitrate respiration at a physiologically relevant rate, whereas NrfH and NosG are not. The iron-sulphur protein NapG was shown to form a complex with NapH in the membrane but was detected in the periplasmic cell fraction in the absence of NapH. Likewise, NosH is able to bind NapG. Each of the eight poly-cysteine motifs present in either NapG or NapH was shown to be essential for nitrate respiration. The NapG homologue NosG could not substitute for NapG, even after adjusting the cysteine spacing to that of NapG, implying that NapG and NosG are specific adapter proteins that channel electrons into either the Nap or Nos system. The current model on the structure and function of the NapGH menaquinol dehydrogenase complex is presented and the composition of the electron transport chains that deliver electrons to periplasmic reductases for either nitrate, nitrite or N₂O is discussed.     

The bacterial protein-translocation complex: SecYEG dimers associate with one or two SecA molecules

In bacteria, the Sec-protein transport complex facilitates the passage of most secretory and membrane proteins across and into the plasma membrane. The core complex SecYEG forms the protein channel and engages either ribosomes or the ATPase SecA, which drive translocation of unfolded polypeptide chains through the complex and into the periplasmic space. Escherichia coli SecYEG forms dimers in membranes, but in detergent solution the population of these dimers is low. However, we find that stable dimers can be assembled by the addition of a monoclonal antibody. Normally, a stable SecYEG-SecA complex can only form on isolated membranes or on reconstituted proteo-liposomes. The antibody-stabilised SecYEG dimer binds one SecA molecule in detergent solution. In the presence of AMPPNP, a non-hydrolysable analogue of ATP, a complex forms containing one antibody and two each of SecYEG and SecA. SecYEG monomers or tetramers do not associate to a significant degree with SecA. The observed variability in the stoichiometry of SecYEG and SecA association and its nucleotide modulation may be important and necessary for the protein translocation reaction.     

Determination of a region of the HisJ binding protein involved in the recognition of the membrane complex of the histidine transport system of Salmonella typhimurium

Site-directed mutagenesis has been utilized to examine the nature of the interaction of the histidine-binding protein (HisJ) with the membrane-bound components of the histidine transport system. In order to examine a region of the HisJ protein involved in the interaction with the membrane components, a number of charged amino acids in the vicinity of the genetically isolated interaction mutant hisJ5625 (R176C) were mutated. It was found that residues Asp171, Arg176, and Asp178 could be independently altered without affecting the histidine-binding affinity of the HisJ protein. However, the alteration of residues Asp171 and Arg176 greatly reduced the interaction of the HisJ protein with the membrane protein complex, whereas altering residue Asp178 had no effect on this interaction. Simultaneously, altering residues Asp183 and Glu184 resulted in a completely defective protein. The ability of a his-J5625 suppressor HisP protein (HisP(T205A)) to suppress the newly created site-directed mutants was also examined. This suppressor demonstrated specificity toward the amino acid present at position 176 and was also able the suppress the mutation created at position 171.     

Preparation and characterization of the water-soluble heme-binding domain of cytochrome c1 from the Rhodobacter sphaeroides bc1 complex.

The ubiquinol:cytochrome c2 oxidoreductase (bc1 complex) of Rhodobacter sphaeroides consists of four subunits. One of these subunits, cytochrome c1, is the site of interaction with cytochrome c2, a periplasmic protein. In addition, the sequences of the fbcC gene and of the cytochrome c1 subunit that it encodes suggest that the protein should be located on the periplasmic side of the cytoplasmic membrane and that it is anchored to the membrane by a single membrane-spanning alpha-helix located at the carboxyl-terminal end of the polypeptide. Site-directed mutagenesis of the fbcC gene was used to alter the codon for Gln228 to a stop codon. This results in the production of a truncated version of the cytochrome c1 subunit that lacks the membrane anchor at the carboxyl terminus. The bc1 complex fails to assemble properly as a result of this mutation, but the Rb. sphaeroides cells expressing the altered gene contain a water-soluble form of cytochrome c1 in the periplasm. The water-soluble cytochrome c1 was purified and characterized. The amino-terminal sequence is identical with that of the membrane-bound subunit, indicating the signal sequence is properly processed. High pressure liquid chromatography gel filtration chromatography indicates it is monomeric (28 kDa). The heme content and electrochemical properties are similar to those of the intact subunit within the complex. Flash-induced electron transfer kinetics measured using whole cells demonstrated that the water-soluble cytochrome c1 is competent as a reductant for cytochrome c2 within the periplasmic space. These data show that the isolated water-soluble cytochrome c1 retains many of the properties of the membrane-bound subunit of the bc1 complex and, therefore, will be useful for further structural and functional characterization.     

The Tmc complex from Desulfovibrio vulgaris hildenborough is involved in transmembrane electron transfer from periplasmic hydrogen oxidation

Three membrane-bound redox complexes have been reported in Desulfovibrio spp., whose genes are not found in the genomes of other sulfate reducers such as Desulfotalea psycrophila and Archaeoglobus fulgidus. These complexes contain a periplasmic cytochrome c subunit of the cytochrome c(3) family, and their presence in these organisms probably correlates with the presence of a pool of periplasmic cytochromes c(3), also absent in the two other sulfate reducers. In this work we report the isolation and characterization of the first of such complexes, Tmc from D. vulgaris Hildenborough, which is associated with the tetraheme type II cytochrome c(3). The isolated Tmc complex contains four subunits, including the TpIIc(3) (TmcA), an integral membrane cytochrome b (TmcC), and two cytoplasmically predicted proteins, an iron-sulfur protein (TmcB) and a tryptophan-rich protein (TmcD). Spectroscopic studies indicate the presence of eight hemes c and two hemes b in the complex pointing to an alpha(2)betagammadelta composition (TmcA(2)BCD). EPR analysis reveals the presence of a [4Fe4S](3+) center and up to three other iron-sulfur centers in the cytoplasmic subunit. Nearly full reduction of the redox centers in the Tmc complex could be obtained upon incubation with hydrogenase/TpIc(3), supporting the role of this complex in transmembrane transfer of electrons resulting from periplasmic oxidation of hydrogen.     

A second trimeric complex containing homologs of the Sec61p complex functions in protein transport across the ER membrane of S. cerevisiae.

Yeast microsomes contain a heptameric Sec complex involved in post-translational protein transport that is composed of a heterotrimeric Sec61p complex and a tetrameric Sec62-Sec63 complex. The trimeric Sec61p complex also exists as a separate entity that probably functions in co-translational protein transport, like its homolog in mammals. We have now discovered in the yeast endoplasmic reticulum membrane a second, structurally related trimeric complex, named Ssh1p complex. It consists of Ssh1p1 (Sec sixty-one homolog 1), a rather distant relative of Sec61p, of Sbh2p, a homolog of the Sbh1p subunit of the Sec61p complex, and of Sss1p, a component common to both trimeric complexes. In contrast to Sec61p, Ssh1p is not essential for cell viability but it is required for normal growth rates. Sbh1p and Sbh2p individually are also not essential, but cells lacking both proteins are impaired in their growth at elevated temperatures and accumulate precursors of secretory proteins; microsomes isolated from these cells also exhibit a reduced rate of post-translational protein transport. Like the Sec61p complex, the Ssh1p complex interacts with membrane-bound ribosomes, but it does not associate with the Sec62-Sec63p complex to form a heptameric Sec complex. We therefore propose that it functions exclusively in the co-translational pathway of protein transport.