Jörg-Christian Greie

Common patterns and unique features of P-type ATPases: a comparative view on the KdpFABC complex from Escherichia coli (Review).

P-type ATPases are ubiquitously abundant primary ion pumps, which are capable of transporting cations across the cell membrane at the expense of ATP. Since these ions comprise a large variety of vital biochemical functions, nature has developed rather sophisticated transport machineries in all kingdoms of life. Due to the importance of these enzymes, representatives of both eu- and prokaryotic as well as archaeal P-type ATPases have been studied intensively, resulting in detailed structural and functional information on their mode of action. During catalysis, P-type ATPases cycle between the so-called E1 and E2 states, each of which comprising different structural properties together with different binding affinities for both ATP and the transport substrate. Crucial for catalysis is the reversible phosphorylation of a conserved aspartate, which is the main trigger for the conformational changes within the protein. In contrast to the well-studied and closely related eukaryotic P-type ATPases, much less is known about their homologues in Bacteria. Whereas in Eukarya there is predominantly only one subunit, which builds up the transport system, in Bacteria there are multiple polypeptides involved in the formation of the active enzyme. Such a rather unusal prokaryotic P-type ATPase is the KdpFABC complex of the enterobacterium Escherichia coli, which serves as a highly specific K+ transporter. A unique feature of this member of P-type ATPases is that catalytic activity and substrate transport are located on two different polypeptides. This review compares generic features of P-type ATPases with the rather unique KdpFABC complex and gives a comprehensive overview of common principles of catalysis as well as of special aspects connected to distinct enzyme functions.

K+-translocating KdpFABC P-type ATPase from Escherichia coli acts as a functional and structural dimer

The membrane-embedded K (+)-translocating KdpFABC complex from Escherichia coli belongs to the superfamily of P-type ATPases, which share common structural features as well as a well-studied catalytic mechanism. However, little is known about the oligomeric state of this class of enzymes. For many P-type ATPases, such as the Na (+)/K (+)-ATPase, Ca (2+)-ATPase, or H (+)-ATPase, an oligomeric state has been shown or is at least discussed but has not yet been characterized in detail. In the KdpFABC complex, kinetic analyses already indicated the presence of two cooperative ATP-binding sides within the functional enzyme and, thus, also point in the direction of a functional oligomer. However, the nature of this oligomeric state has not yet been fully elucidated. In the present work, a close vicinity of two KdpB subunits within the functional KdpFABC complex could be demonstrated by chemical cross-linking of native cysteine residues using copper 1,10-phenanthroline. The cysteines responsible for cross-link formation were identified by mutagenesis. Cross-linked and non-cross-linked KdpFABC complexes eluted with the same apparent molecular weight during gel filtration, which corresponded to the molecular weight of a homodimer, thereby clearly indicating that the KdpFABC complex was purified as a dimer. Isolated KdpFABC complexes were analyzed by transmission electron microscopy and exhibited an approximately 1:1 distribution of mono- and dimeric particles. Finally, reconstituted functional KdpFABC complexes were site-directedly labeled with flourescent dyes, and intermolecular single-molecule FRET analysis was carried out, from which a dissociation constant for a monomer/dimer equilibrium between 30 and 50 nM could be derived.

The ATP synthase of Escherichia coli: structure and function of F0 subunits

In this review we discuss recent work from our laboratory concerning the structure and/or function of the F(0) subunits of the proton-translocating ATP synthase of Escherichia coli. For the topology of subunit a a brief discussion gives (i) a detailed picture of the C-terminal two-thirds of the protein with four transmembrane helices and the C terminus exposed to the cytoplasm and (ii) an evaluation of the controversial results obtained for the localization of the N-terminal region of subunit a including its consequences on the number of transmembrane helices. The structure of membrane-bound subunit b has been determined by circular dichroism spectroscopy to be at least 75% alpha-helical. For this purpose a method was developed, which allows the determination of the structure composition of membrane proteins in proteoliposomes. Subunit b was purified to homogeneity by preparative SDS gel electrophoresis, precipitated with acetone, and redissolved in cholate-containing buffer, thereby retaining its native conformation as shown by functional coreconstitution with an ac subcomplex. Monoclonal antibodies, which have their epitopes located within the hydrophilic loop region of subunit c, and the F(1) part are bound simultaneously to the F(0) complex without an effect on the function of F(0), indicating that not all c subunits are involved in F(1) interaction. Consequences on the coupling mechanism between ATP synthesis/hydrolysis and proton translocation are discussed.

Subunit Organization of the Stator Part of the F 0 Complex from Escherichia coli ATP Synthase

Membrane-bound ATP synthases (F1F0) catalyze the synthesis of ATP via a rotary catalyticmechanism utilizing the energy of an electrochemical ion gradient. The transmembrane potentialis supposed to propel rotation of a subunit c ring of F0 together with subunits γ and ∈ of F1,hereby forming the rotor part of the enzyme, whereas the remainder of the F1F0 complexfunctions as a stator for compensation of the torque generated during rotation. This reviewfocuses on our recent work on the stator part of the F0 complex, e.g., subunits a and b. Usingepitope insertion and antibody binding, subunit a was shown to comprise six transmembranehelixes with both the N- and C-terminus oriented toward the cytoplasm. By use of circulardichroism (CD) spectroscopy, the secondary structure of subunit b incorporated intoproteoliposomes was determined to be 80% α-helical together with 14% β turn conformation, providingflexibility to the second stalk. Reconstituted subunit b together with isolated ac subcomplexwas shown to be active in proton translocation and functional F1 binding revealing the nativeconformation of the polypeptide chain. Chemical crosslinking in everted membrane vesiclesled to the formation of subunit b homodimers around residues bQ37 to bL65, whereas bA32Ccould be crosslinked to subunit a, indicating a close proximity of subunits a and b near themembrane. Further evidence for the proposed direct interaction between subunits a and b wasobtained by purification of a stable ab2 subcomplex via affinity chromatography using Histags fused to subunit a or b. This ab2 subcomplex was shown to be active in proton translocationand F1 binding, when coreconstituted with subunit c. Consequences of crosslink formationand subunit interaction within the F1F0 complex are discussed.

Individual interactions of the b subunits within the stator of the Escherichia coli ATP synthase.

Background: The peripheral stator stalk of Escherichia coli ATP synthase contains two b subunits. Results: Using disulfide bond formation, one b subunit was cross-linked to a, α, and δ and the other to β. Conclusion: The b subunits adopt distinct positions within the stator to generate stability. Significance: The different positions imply different roles in counteracting the torque generated by the rotor. FOF1 ATP synthases are rotary nanomotors that couple proton translocation across biological membranes to the synthesis/hydrolysis of ATP. During catalysis, the peripheral stalk, composed of two b subunits and subunit δ in Escherichia coli, counteracts the torque generated by the rotation of the central stalk. Here we characterize individual interactions of the b subunits within the stator by use of monoclonal antibodies and nearest neighbor analyses via intersubunit disulfide bond formation. Antibody binding studies revealed that the C-terminal region of one of the two b subunits is principally involved in the binding of subunit δ, whereas the other one is accessible to antibody binding without impact on the function of FOF1. Individually substituted cysteine pairs suitable for disulfide cross-linking between the b subunits and the other stator subunits (b-α, b-β, b-δ, and b-a) were screened and combined with each other to discriminate between the two b subunits (i.e. bI and bII). The results show the b dimer to be located at a non-catalytic α/β cleft, with bI close to subunit α, whereas bII is proximal to subunit β. Furthermore, bI can be linked to subunit δ as well as to subunit a. Among the subcomplexes formed were a-bI-α, bII-β, α-bI-bII-β, and a-bI-δ. Taken together, the data obtained define the different positions of the two b subunits at a non-catalytic interface and imply that each b subunit has a different role in generating stability within the stator. We suggest that bI is functionally related to the single b subunit present in mitochondrial ATP synthase.

The KdpFABC complex from Escherichia coli: a chimeric K+ transporter merging ion pumps with ion channels.

The KdpFABC complex represents a multi-subunit ATP-driven potassium pump, which is only found in bacteria and archaea. Based on the properties of the ATP-hydrolyzing subunit (KdpB) the transporter has been classified as a type IA P-type ATPase. However, structural and functional properties of the remaining subunits clearly show homologies to members of the potassium channel as well as the ABC transporter family, thus rendering the KdpFABC complex to represent an inimitable chimera of ion pumps and ion channels. Accordingly, this striking juxtaposition entails special features of KdpFABC with respect to typical members of each of the transporter families, involving not only the concepts but also the structures of ion channels and ion pumps. For example, the sites of ATP hydrolysis and substrate transport are spatially separated on two different polypeptides, which, in turn, leads to a unique coupling mechanism. During catalysis, the KdpFABC complex cycles between two main conformational states, each of which comprises different structural properties together with different binding affinities for both ATP and the transport substrate. These structural configurations have recently been directly visualized in the working enzyme. Translocation of potassium is mediated by the KdpA subunit, which comprises structural as well as functional homologies to potassium channels of the MPM-type. The KdpC subunit participates in the binding of ATP, thus acting as a catalytic chaperone, which increases the ATP binding affinity of the KdpB subunit via a mechanism typical of nucleotide binding in ABC transporters.

Monitoring the conformational dynamics of a single potassium transporter by ALEX-FRET

Conformational changes of single proteins are monitored in real time by Förster-type resonance energy transfer, FRET. Two different fluorophores have to be attached to those protein domains, which move during function. The distance between the fluorophores is measured by relative fluorescence intensity changes of FRET donor and acceptor fluorophore, or by fluorescence lifetime changes of the FRET donor. The fluorescence spectrum of a single FRET donor fluorophore is influenced by local protein environment dynamics causing apparent fluorescence intensity changes on the FRET donor and acceptor detector channels. To discriminate between those spectral fluctuations and distance-dependent FRET, alternating pulsed excitation schemes (ALEX) have recently been introduced which simultaneously probe the existence of a FRET acceptor fluorophore. Here we employ single-molecule FRET measurements to a membrane protein. The membrane-embedded KdpFABC complex transports potassium ions across a lipid bilayer using ATP hydrolysis. Our study aims at the observation of conformational fluctuations within a single P-type ATPase functionally reconstituted into liposomes by single-molecule FRET and analysis by Hidden-Markov-Models.

The KdpC subunit of the Escherichia coli K+‐transporting KdpB P‐type ATPase acts as a catalytic chaperone

In Bacteria and Archaea, high‐affinity potassium uptake is mediated by the ATP‐driven KdpFABC complex. On the basis of the biochemical properties of the ATP‐hydrolyzing subunit KdpB, the transport complex is classified as type IA P‐type ATPase. However, the KdpA subunit, which promotes K+ transport, clearly resembles a potassium channel, such that the KdpFABC complex represents a chimera of ion pumps and ion channels. In the present study, we demonstrate that the blending of these two groups of transporters in KdpFABC also entails a nucleotide‐binding mechanism in which the KdpC subunit acts as a catalytic chaperone. This mechanism is found neither in P‐type ATPases nor in ion channels, although parallels are found in ABC transporters. In the latter, the ATP nucleotide is coordinated by the LSGGQ signature motif via double hydrogen bonds at a conserved glutamine residue, which is also present in KdpC. High‐affinity nucleotide binding to the KdpFABC complex was dependent on the presence of this conserved glutamine residue in KdpC. In addition, both ATP binding to KdpC and ATP hydrolysis activity of KdpFABC were sensitive to the accessibility, presence or absence of the hydroxyl groups at the ribose moiety of the nucleotide. Furthermore, the KdpC subunit was shown to interact with the nucleotide‐binding loop of KdpB in an ATP‐dependent manner around the ATP‐binding pocket, thereby increasing the ATP‐binding affinity by the formation of a transient KdpB/KdpC/ATP ternary complex.

Archaeal transcriptional regulation of the prokaryotic KdpFABC complex mediating K + uptake in H. salinarum

The genome of the halophilic archaeon Halobacterium salinarum encodes the high-affinity ATP-dependent K+ uptake system Kdp. Previous studies have shown that the genes coding for the KdpFABC complex are arranged in a kdpFABCQ gene cluster together with an additional gene kdpQ. In bacteria, expression of the kdpFABC genes is generally regulated by the dedicated sensor kinase/response regulator pair KdpD/KdpE, which are absent in H. salinarum. Surprisingly, H. salinarum expresses the kdp genes in a manner which is strikingly similar to Escherichia coli. In this study, we show that the halobacterial kdpFABCQ genes constitute an operon and that kdpFABCQ expression is subject to a complex regulatory mechanism involving a negative transcriptional regulator and is further modulated via a so far unknown mechanism. We describe how the regulation of kdp gene expression is facilitated in H. salinarum in contrast to its bacterial counterparts. Whereas the Kdp system fulfils the same core function as an ATP-driven K+ uptake system in both archaea and bacteria, the different mechanisms involved in the regulation of gene expression appear to have evolved separately, possibly reflecting a different physiological role of ATP-driven K+ uptake in halophilic archaea.

Mechanistic analysis of the pump cycle of the KdpFABC P-type ATPase.

The high-affinity potassium uptake system KdpFABC is a unique type Ia P-type ATPase, because it separates the sites of ATP hydrolysis and ion transport on two different subunits. KdpFABC was expressed in Escherichia coli. It was then isolated and purified to homogeneity to obtain a detergent-solubilized enzyme complex that allowed the analysis of ion binding properties. The electrogenicity and binding affinities of the ion pump for K(+) and H(+) were determined in detergent-solubilized complexes by means of the electrochromic styryl dye RH421. Half-saturating K(+) concentrations and pK values for H(+) binding could be obtained in both the unphosphorylated and phosphorylated conformations of KdpFABC. The interaction of both ions with KdpFABC was studied in detail, and the presence of independent binding sites was ascertained. It is proposed that KdpFABC reconstituted in vesicles translocates protons at a low efficiency opposite from the well-established import of K(+) into the bacteria. On the basis of our results, various mechanistic pump cycle models were derived from the general Post-Albers scheme of P-type ATPases and discussed in the framework of the experimental evidence to propose a possible molecular pump cycle for KdpFABC.