Erwin Schneider

NAD+ binding to the Escherichia coli K+-uptake protein TrkA and sequence similarity between TrkA and domains of a family of dehydrogenases suggest a role for NAD+ in bacterial transport

The nucleotide sequence of trkA, a gene encoding a surface component of the constitutive K+‐uptake systems TrkG and TrkH from Escherichia coli, was determined. The structure of the TrkA protein deduced from the nucleotide sequence accords with the view that TrkA is peripherally bound to the inner side of the cytoplasmic membrane. Analysis by a dot matrix revealed that TrkA is composed of similar halves. The M‐terminal part of each TrkA half (residues 1–130 and 234–355, respectively) is similar to the complete NAD+‐binding domain of NAD+‐dependent dehydrogenases. The C‐terminal part of each TrkA half (residues 131–233 and 357–458, respectively) aligns with the first 100 residues of the catalytic domain of glyceraldehyde‐3‐phosphate dehydrogenase. Strong u.v. illumination at 252 nm led to cross‐linking of NAD+ or NADH, but not of ATP to the isolated TrkA protein.

ABC transporters catalyzing carbohydrate uptake.

ATP binding cassette (ABC) transporters mediating the uptake of carbohydrates comprise two subfamilies (CUT1, CUT2) that differ with respect to the chemical nature of their substrates, subunit composition, and conserved sequence motifs. In this article, current knowledge of members of each family is summarized with special emphasis on the well-characterized transport systems for maltose/maltodextrin and ribose, respectively, of enterobacteria.

The maltose ATP‐binding cassette transporter in the 21st century – towards a structural dynamic perspective on its mode of action

The maltose/maltodextrin transport system of Escherichia coli/Salmonella, composed of periplasmic maltose‐binding protein, MalE, the pore‐forming subunits MalF and MalG, and a homodimer of the nucleotide‐binding subunit, MalK, serves as a model for canonical ATP‐binding cassette importers in general. The wealth of knowledge accumulated on the maltose transporter in more than three decades by genetic, molecular genetic and biochemical means was complemented more recently by crystal structures of the isolated MalK dimer and of two conformational states of the full transporter. Here, we summarize insights into the transport mechanism provided by these structures and draw the readers attention to experimental tools by which the dynamics of the transporter can be studied during substrate translocation. A transport model is presented that integrates currently available biochemical, biophysical and structural data. We also present the state of knowledge on regulatory functions of the maltose transporter associated with the C‐terminal domain of MalK. Finally, we will address the application of coarse‐grained modelling to visualize the progression of the conformational changes of an ABC transporter with special emphasis on the maltose system, which can provide a model platform for testing and validating the bioinformatic tools.

Transmembrane Signaling in the Maltose ABC Transporter MalFGK2-E PERIPLASMIC MalF-P2 LOOP COMMUNICATES SUBSTRATE AVAILABILITY TO THE ATP-BOUND MalK DIMER

ABC transporters are ubiquitous membrane proteins that translocate solutes across biological membranes at the expense of ATP. In prokaryotic ABC importers, the extracytoplasmic anchoring of the substrate-binding protein (receptor) is emerging as a key determinant for the structural rearrangements in the cytoplasmically exposed ATP-binding cassette domains and in the transmembrane gates during the nucleotide cycle. Here the molecular mechanism of such signaling events was addressed by electron paramagnetic resonance spectroscopy of spin-labeled ATP-binding cassette maltose transporter variants (MalFGK2-E). A series of doubly spin-labeled mutants in the MalF-P2 domain involving positions 92, 205, 239, 252, and 273 and one triple mutant labeled at positions 205/252 in P2 and 83 in the Q-loop of MalK were assayed. The EPR data revealed that the substrate-binding protein MalE is bound to the transporter throughout the transport cycle. Concomitantly with the three conformations of the ATP-binding cassette MalK2, three functionally relevant conformations are found also in the periplasmic MalF-P2 loop, strictly dependent on cytoplasmic nucleotide binding and periplasmic docking of liganded MalE to MalFG. The reciprocal communication across the membrane unveiled here gives first insights into the stimulatory effect of MalE on the ATPase activity, and it is suggested to be an important mechanistic feature of receptor-coupled ABC transporters.

The maltose ABC transporter in the 21st century ? towards a structural-dynamic perspective on its mode of action

The maltose/maltodextrin transport system of Escherichia coli/Salmonella, composed of periplasmic maltose‐binding protein, MalE, the pore‐forming subunits MalF and MalG, and a homodimer of the nucleotide‐binding subunit, MalK, serves as a model for canonical ATP‐binding cassette importers in general. The wealth of knowledge accumulated on the maltose transporter in more than three decades by genetic, molecular genetic and biochemical means was complemented more recently by crystal structures of the isolated MalK dimer and of two conformational states of the full transporter. Here, we summarize insights into the transport mechanism provided by these structures and draw the readers attention to experimental tools by which the dynamics of the transporter can be studied during substrate translocation. A transport model is presented that integrates currently available biochemical, biophysical and structural data. We also present the state of knowledge on regulatory functions of the maltose transporter associated with the C‐terminal domain of MalK. Finally, we will address the application of coarse‐grained modelling to visualize the progression of the conformational changes of an ABC transporter with special emphasis on the maltose system, which can provide a model platform for testing and validating the bioinformatic tools.

Maltose and Maltodextrin Transport in the Thermoacidophilic Gram-Positive Bacterium Alicyclobacillus acidocaldarius Is Mediated by a High-Affinity Transport System That Includes a Maltose Binding Protein Tolerant to Low pH

We have studied the uptake of maltose in the thermoacidophilic gram-positive bacterium Alicyclobacillus acidocaldarius, which grows best at 57 degrees C and pH 3.5. Under these conditions, accumulation of [(14)C]maltose was observed in cells grown with maltose but not in those grown with glucose. At lower temperatures or higher pH values, the transport rates substantially decreased. Uptake of radiolabeled maltose was inhibited by maltotetraose, acarbose, and cyclodextrins but not by lactose, sucrose, or trehalose. The kinetic parameters (K(m) of 0.91 +/- 0.06 microM and V(max) ranging from 0.6 to 3.7 nmol/min/mg of protein) are consistent with a binding protein-dependent ATP binding cassette (ABC) transporter. A corresponding binding protein (MalE) that interacts with maltose with high affinity (K(d) of 1.5 microM) was purified from the culture supernatant of maltose-grown cells. Immunoelectron microscopy revealed distribution of the protein throughout the cell wall. The malE gene was cloned and sequenced. Five additional open reading frames, encoding components of a maltose transport system (MalF and MalG), a putative transcriptional regulator (MalR), a cyclodextrinase (CdaA), and an alpha-glucosidase (GlcA), were identified downstream of malE. The malE gene lacking the DNA sequence that encodes the signal sequence was expressed in Escherichia coli. The purified wild-type and recombinant proteins bind maltose with high affinity over a wide pH range (2.5 to 7) and up to 80 degrees C. Recombinant MalE cross-reacted with an antiserum raised against the wild-type protein, thereby indicating that the latter is the product of the malE gene. The MalE protein might be well suited as a model to study tolerance of proteins to low pH.

A putative helical domain in the MalK subunit of the ATP‐binding‐cassette transport system for maltose of Salmonella typhimurium (MalFGK2) is crucial for interaction with MalF and MalG. A study using the LacK protein of Agrobacterium radiobacter as a tool.

The ATP‐binding‐cassette (ABC) protein LacK of Agro‐bacterium radiobacter displays high sequence similarity to the MalK subunit of the Salmonella typhimurium maltose‐transport system (MalFGK2). We have used LacK as a tool to identify sites of interaction of MalK with the membrane‐integral components MalF and MalG. Small amounts of LacK, resulting from the expression of the plasmid‐borne lacK gene, proved to be sufficient for partial restoration of growth of a malK strain of S. typhimurium on maltose. LacK failed to substitute for MalK in regulating the expression of maltose‐inducible genes but the hybrid complex MalFGLacK2 was sensitive to inducer exclusion. The lacK gene also complemented a ugpC mutant of Escherichia coli to growth on sn‐glycerol‐3‐phosphate as the phosphate source. Partially purified LacK exhibited a spontaneous ATPase activity comparable to that of MalK. A MalK′–′LacK chimeric protein was isolated (by in vivo recombination) in which the N‐terminal 140 amino acids of MalK are fused to residues 141–363 of LacK. The protein substituted for MalK in maltose transport considerably better than LacK. Furthermore, random mutagenesis of the plasmid‐borne lacK gene yielded three clones that were superior to wild‐type lacK in complementing a malK mutation. Single mutations (V114M or L123F) substantially improved the growth of a malK strain on maltose, whereas a double mutation (L123F, S295N) resulted in growth and transport rates that were indistinguishable from those obtained with MalK. In contrast, the introduction of the single change S295N into LacK had no effect but combination with the V114M mutation led to a further twofold increase in transport activity. These results indicate that a putative helical domain in MalK, encompassing residues 89–140, is crucial for a functional, high‐affinity interaction with MalF and MalG.

ATP-driven MalK Dimer Closure and Reopening and Conformational Changes of the “EAA” Motifs Are Crucial for Function of the Maltose ATP-binding Cassette Transporter (MalFGK2)

We have investigated conformational changes of the purified maltose ATP-binding cassette transporter (MalFGK2) upon binding of ATP. The transport complex is composed of a heterodimer of the hydrophobic subunits MalF and MalG constituting the translocation pore and of a homodimer of MalK, representing the ATP-hydrolyzing subunit. Substrate is delivered to the transporter in complex with periplasmic maltose-binding protein (MalE). Cross-linking experiments with a variant containing an A85C mutation within the Q-loop of each MalK monomer indicated an ATP-induced shortening of the distance between both monomers. Cross-linking caused a substantial inhibition of MalE-maltose-stimulated ATPase activity. We further demonstrated that a mutation affecting the “catalytic carboxylate” (E159Q) locks the MalK dimer in the closed state, whereas a transporter containing the “ABC signature” mutation Q140K permanently resides in the resting state. Cross-linking experiments with variants containing the A85C mutation combined with cysteine substitutions in the conserved EAA motifs of MalF and MalG, respectively, revealed close proximity of these residues in the resting state. The formation of a MalK-MalG heterodimer remained unchanged upon the addition of ATP, indicating that MalG-EAA moves along with MalK during dimer closure. In contrast, the yield of MalK-MalF dimers was substantially reduced. This might be taken as further evidence for asymmetric functions of both EAA motifs. Cross-linking also caused inhibition of ATPase activity, suggesting that transporter function requires conformational changes of both EAA motifs. Together, our data support ATP-driven MalK dimer closure and reopening as crucial steps in the translocation cycle of the intact maltose transporter and are discussed with respect to a current model.

ATP Induces Conformational Changes of Periplasmic Loop Regions of the Maltose ATP-binding Cassette Transporter

We have studied cofactor-induced conformational changes of the maltose ATP-binding cassette transporter by employing limited proteolysis in detergent solution. The transport complex consists of one copy each of the transmembrane subunits, MalF and MalG, and of two copies of the nucleotide-binding subunit, MalK. Transport activity further requires the periplasmic maltose-binding protein, MalE. Binding of ATP to the MalK subunits increased the susceptibility of two tryptic cleavage sites in the periplasmic loops P2 of MalF and P1 of MalG, respectively. Lys262 of MalF and Arg73 of MalG were identified as probable cleavage sites, resulting in two N-terminal peptide fragments of 29 and 8 kDa, respectively. Trapping the complex in the transition state by vanadate further stabilized the fragments. In contrast, the tryptic cleavage profile of MalK remained largely unchanged. ATP-induced conformational changes of MalF-P2 and MalG-P1 were supported by fluorescence spectroscopy of complex variants labeled with 2-(4′-maleimidoanilino)naphthalene-6-sulfonic acid. Limited proteolysis was subsequently used as a tool to study the consequences of mutations on the transport cycle. The results suggest that complex variants exhibiting a binding protein-independent phenotype (MalF500) or containing a mutation that affects the “catalytic carboxylate” (MalKE159Q) reside in a transition state-like conformation. A similar conclusion was drawn for a complex containing a replacement of MalKQ140 in the signature sequence by leucine, whereas substitution of lysine for Gln140 appears to lock the transport complex in the ground state. Together, our data provide the first evidence for conformational changes of the transmembrane subunits of an ATP-binding cassette import system upon binding of ATP.

Large-scale purification, dissociation and functional reassembly of the maltose ATP-binding cassette transporter (MalFGK2) of Salmonella typhimurium

Abstract The maltose ATP-binding cassette (ABC) transporter of Salmonella typhimurium is composed of a membrane-associated complex (MalFGK 2 ) and a periplasmic substrate binding protein. To further elucidate protein–protein interactions between the subunits, we have studied the dissociation and reassembly of the MalFGK 2 complex at the level of purified components in proteoliposomes. First, we optimized the yield in purified complex protein by taking advantage of a newly constructed expression plasmid that carries the malK , malF and malG genes in tandem orientation. Incorporated in proteoliposomes, the complex exhibited maltose binding protein/maltose-dependent ATPase activity with a V max of 1.25 μmol P i /min/mg and a K m of 0.1 mM. ATPase activity was sensitive to vanadate and enzyme IIA Glc , a component of the enterobacterial glucose transport system. The proteoliposomes displayed maltose transport activity with an initial rate of 61 nmol/min/mg. Treatment of proteoliposomes with 6.6 M urea resulted in the release of medium-exposed MalK subunits concomitant with the complete loss of ATPase activity. By adding increasing amounts of purified MalK to urea-treated proteoliposomes, about 50% of vanadate-sensitive ATPase activity relative to the control could be recovered. Furthermore, the phenotype of MalKQ140K that exhibits ATPase activity in solution but not when associated with MalFG was confirmed by reassembly with MalK-depleted proteoliposomes.