Escherichia coli minicell membranes are enriched in cardiolipin.

The phospholipid composition of Escherichia coli minicells has been studied as a model for the cell division site. Minicells appeared to be enriched in cardiolipin at the expense of phosphatidylglycerol. Mass spectrometry showed no differences between the gross acyl chain compositions of minicells and wild-type cells.

Substitution of a conserved aspartate allows cation-induced polymerization of FtsZ.

The prokaryotic tubulin homologue FtsZ polymerizes in vitro in a nucleotide dependent fashion. Here we report that replacement of the strictly conserved Asp212 residue of Escherichia coli FtsZ by a Cys or Asn, but not by a Glu residue results in FtsZ that polymerizes with divalent cations in the absence of added GTP. FtsZ D212C and D212N mutants co-purify with GTP as bound nucleotide, providing an explanation for the unusual phenotype. We conclude that D212 plays a critical role in the coordination of a metal ion and the nucleotide at the interface of two FtsZ monomers.

Distribution of the Escherichia coli structural maintenance of chromosomes (SMC)-like protein MukB in the cell.

Fluorescent polyclonal antibodies specific for MukB have been used to study its localization in Escherichia coli. In wild-type cells, the MukB protein appeared as a limited number of oblong shapes embracing the nucleoid. MukB remained associated with the nucleoid in the absence of DNA replication. The centre of gravity of the dispersed MukB signal initially localized near mid-cell, but moved to approximately quarter positions well before the termination of DNA replication and its subsequent reinitiation. Because MukB had been reported to bind to FtsZ and to its eukaryotic homologue tubulin in vitro, cells were co-labelled with MukB- and FtsZ-specific fluorophores. No co-localization of MukB with polymerized FtsZ (the FtsZ ring) was observed at any time during the cell cycle. A possible role for MukB in preventing premature FtsZ polymerization and in DNA folding that might assist DNA segregation is discussed.

Non-hydrolysable GTP-gamma-S stabilizes the FtsZ polymer in a GDP-bound state.

FtsZ, a tubulin homologue, forms a cytokinetic ring at the site of cell division in prokaryotes. The ring is thought to consist of polymers that assemble in a strictly GTP-dependent way. GTP, but not guanosine-5'-O-(3-thiotriphosphate) (GTP-gamma-S), has been shown to induce polymerization of FtsZ, whereas in vitro Ca2+ is known to inhibit the GTP hydrolysis activity of FtsZ. We have studied FtsZ dynamics at limiting GTP concentrations in the presence of 10 mM Ca2+. GTP and its non-hydrolysable analogue GTP-gamma-S bind FtsZ with similar affinity, whereas the non-hydrolysable analogue guanylyl-imidodiphosphate (GMP-PNP) is a poor substrate. Preformed FtsZ polymers can be stabilized by GTP-gamma-S and are destabilized by GDP. As more than 95% of the nucleotide associated with the FtsZ polymer is in the GDP form, it is concluded that GTP hydrolysis by itself does not trigger FtsZ polymer disassembly. Strikingly, GTP-gamma-S exchanges only a small portion of the FtsZ polymer-bound GDP. These data suggest that FtsZ polymers are stabilized by a small fraction of GTP-containing FtsZ subunits. These subunits may be located either throughout the polymer or at the polymer ends, forming a GTP cap similar to tubulin.

Thermodynamics of nucleotide binding to NBS-I of the Bacillus subtilis preprotein translocase subunit SecA.

SecA is the dissociatable nucleotide and preprotein binding subunit of the bacterial translocase. The thermodynamics of nucleotide binding to soluble SecA at nucleotide binding site I were determined by isothermal titration calorimetry. Binding of ADP and non-hydrolyzable ATPgammaS is enthalpy-driven (DeltaH(0) of -14.44 and -5.56 kcal/mol, respectively), but is accompanied by opposite entropic contributions (DeltaS(0) of -18.25 and 9.55 cal/mol/K, respectively). ADP binding results in a large change in the heat capacity of SecA (DeltaC(p)=-780 cal/mol/K). It is suggested that ADP binding promotes the interaction between the two thermodynamically discernible domains of SecA which is accompanied by a shielding of hydrophobic surface from solvent.

Timing of FtsZ assembly in Escherichia coli.

The timing of the appearance of the FtsZ ring at the future site of division in Escherichia coli was determined by in situ immunofluorescence microscopy for two strains grown under steady-state conditions. The strains, B/rA and K-12 MC4100, differ largely in the duration of the D period, the time between termination of DNA replication and cell division. In both strains and under various growth conditions, the assembly of the FtsZ ring was initiated approximately simultaneously with the start of the D period. This is well before nucleoid separation or initiation of constriction as determined by fluorescence and phase-contrast microscopy. The durations of the Z-ring period, the D period, and the period with a visible constriction seem to be correlated under all investigated growth conditions in these strains. These results suggest that (near) termination of DNA replication could provide a signal that initiates the process of cell division.

Outer membrane protein A of Escherichia coli inserts and folds into lipid bilayers by a concerted mechanism.

Unfolded outer membrane protein A (OmpA) of Escherichia coli spontaneously inserts and refolds into lipid bilayers upon dilution of denaturing urea. In the accompanying paper, we have developed a new technique, time-resolved distance determination by fluorescence quenching (TDFQ), which is capable of monitoring the translocation across lipid bilayers of fluorescence reporter groups such as tryptophan in real time [Kleinschmidt, J. H., and Tamm, L. K. (1999) Biochemistry 38, 4996-5005]. Specifically, we have shown that wild-type OmpA, which contains five tryptophans, inserts into lipid bilayers via three structurally distinct membrane-bound folding intermediates. To take full advantage of the TDFQ technique and to further dissect the folding pathway, we have made five different mutants of OmpA, each containing a single tryptophan and four phenylalanines in the five tryptophan positions of the wild-type protein. All mutants refolded in vivo and in vitro and, as judged by SDS-PAGE, trypsin fragmentation, and Trp fluorescence, their refolded state was indistinguishable from the native state of OmpA. TDFQ analysis of the translocation across the lipid bilayer of the individual Trps of OmpA yielded the following results: Below 30 degrees C, all Trps started from a far distance from the bilayer center and then gradually approached a distance of approximately 10 A from the bilayer center. In a narrow temperature range between 30 and 35 degrees C, Trp-15, Trp-57, Trp-102, and Trp-143 were detected very close to the center of the lipid bilayer in the first few minutes and then moved to greater distances from the center. When monitored at 40 degrees C, which resolved the last steps of OmpA refolding, these four tryptophans crossed the center of the bilayer and approached distances of approximately 10 A from the center after refolding was complete. In contrast Trp-7 approached the 10 A distance from a far distance at all temperatures and was never detected to cross the center of the lipid bilayer. The translocation rates of Trp-15, Trp-57, Trp-102, and Trp-143 which are each located in different outer loop regions of the four beta-hairpins of the eight-stranded beta-barrel of OmpA were very similar to one another. This result and the common distances of these Trps from the membrane center observed in the third membrane-bound folding intermediate provide strong evidence for a synchronous translocation of all four beta-hairpins of OmpA across the lipid bilayer and suggest that OmpA inserts and folds into lipid bilayers by a concerted mechanism.

Interaction of SecB with soluble SecA.

The preprotein binding molecular chaperone SecB functions by preventing the premature folding of the preprotein in the cytosol, and targeting it to the peripheral subunit SecA of the translocase at the cytoplasmic membrane. The nature of the interaction of SecB with soluble SecA was studied by fluorescence anisotropy spectroscopy of Ru(bpy)2(dcbpy)-labeled SecA in the presence of increasing concentrations of SecB. A more than 50-fold difference in affinity for the cytosolic SecA compared to translocase associated SecA seems to prevent unproductive binding of SecB to the cytosolic SecA and stresses its targeting function.

Inhibition of preprotein translocation and reversion of the membrane inserted state of SecA by a carboxyl terminus binding mAb.

SecA is the peripheral subunit of the preprotein translocase of Escherichia coli. SecA consists of two independently folding domains, i.e., the N-domain bearing the high-affinity nucleotide binding site (NBS-I) and the C-domain that harbors the low-affinity NBS-II. ATP induces SecA insertion into the membrane during preprotein translocation. Domain-specific monoclonal antibodies (mAbs) were developed to analyze the functions of the SecA domains in preprotein translocation. The antigen binding sites of the obtained mAbs were confined to five epitopes. One of the mAbs, i.e., mAb 300-1K5, recognizes an epitope in the C-domain in a region that has been implicated in membrane insertion. This mAb, either as IgG or as Fab, completely inhibits in vitro proOmpA translocation and SecA translocation ATPase activity. It prevents SecA membrane insertion and, more strikingly, reverses membrane insertion and promotes the release of SecA from the membrane. Surface plasmon resonance measurements demonstrate that the mAb recognizes the ADP- and the AMP-PNP-bound state of SecA either free in solution or bound at the membrane at the SecYEG protein. It is concluded that the mAb actively reverses a conformation essential for membrane insertion of SecA. The other mAbs directed to various epitopes in the N-domain were found to be without effect, although all bind the native SecA. These results demonstrate that the C-domain plays an important role in the SecA membrane insertion, providing further evidence that this process is needed for preprotein translocation.

Crystal structures of modified apo-His117Gly and apo-His46Gly mutants of Pseudomonas aeruginosa azurin.

The X-ray crystal structures of two metal ligand mutants of azurin from Pseudomonas aeruginosa have been solved. In both mutants (His117Gly and His46Gly azurin) one of the copper coordinating histidine residues is replaced by a glycine, creating an empty space in the coordination sphere of the copper ion. The crystal structure of His117Gly azurin at 2.4 A resolution showed that this mutant had undergone partial oxidation at the disulfide bridge between Cys3 and Cys26 and full oxidation at the copper ligand Cys112. There is no copper present in the crystallized form and the bulky group of the oxidized cysteine at position 112 causes large structural rearrangements in the protein structure, especially in the loops connecting the beta-sheets. In the structure of the wild-type holo-azurin from P. aeruginosa the hydrophobic patch is important for the packing of the azurin molecules into dimers which then arrange into tetramers. The completely different packing of the apo-His117Gly mutant can be explained by the disruption of the hydrophobic patch area by the mutation-induced main-chain conformational change of residues 112 to 115. The structure of apo-His46Gly azurin at 2.5 A resolution is the same as the wild-type structure except for the immediate environment at the site of the mutation. In the His46Gly structure water molecules are found at positions that in the wild-type structure are occupied by the imidazole ring of His46 and the copper ion. The imidazole ring of His117 is shifted by about 1 A towards the surface of the protein, similar to that observed for 50% of the molecules in the wild-type apo-azurin structure. This shift causes a slight rearrangement of the monomers within the tetramer such that one local dyad becomes a crystallographic dyad parallel to the c-axis. This leads to a change in the space group from P2(1)2(1)2(1) to P2(1)2(1)2.

SecA is an intrinsic subunit of the Escherichia coli preprotein translocase and exposes its carboxyl terminus to the periplasm.

SecA is the dissociable ATPase subunit of the Escherichia coli preprotein translocase, and cycles in a nucleotide-modulated manner between the cytosol and the membrane. Overproduction of the integral subunits of the translocase, the SecY, SecE and SecG polypeptides, results in an increased level of membrane-bound SecA. This fraction of SecA is firmly associated with the membrane as it is resistant to extraction with the chaotropic agent urea, and appears to be anchored by SecYEG rather than by lipids. Topology analysis of this membrane-associated form of SecA indicates that it exposes a carboxy-terminal domain to the periplasmic face of the membrane.

Dimerization of a His117Gly azurin mutant by external addition of 1,omega-di(imidazol-1-yl)alkanes.

The possibility to construct non-covalently linked protein dimers was investigated by employing the His117Gly mutant of the Cu containing azurin and the bifunctional 1,omega-di(imidazol-1-yl)alkanes as linkers. The His117Gly mutation creates a gap in the coordination sphere of the metal through which the latter becomes accessible for externally added ligands. The bifunctional ligands gave rise to the formation of dimers provided the linker was sufficiently long, as in the case of 1,omega-di(imidazol-1-yl)pentane and -hexane; the butane linker only produced monomers. The binding of the azurin molecules to the bifunctional C5 and C6 linkers showed cooperativity, which is the result of the hydrophobic interaction of the aligned hydrophobic patches. The energy and surface area involved in this process have been estimated from the experimental data to be delta G is -1.3 to -2.1 kcal/mol and 65-105 A2. The implications for the study of electron transfer processes inside a protein matrix are indicated.

Domain interactions of the peripheral preprotein Translocase subunit SecA.

The homodimeric SecA protein is the peripheral subunit of the preprotein translocase in bacteria. It binds the preprotein and promotes its translocation across the bacterial cytoplasmic membrane by nucleotide modulated coinsertion and deinsertion into the membrane. SecA has two essential nucleotide binding sites (NBS; Mitchell & Oliver, 1993): The high-affinity NBS-I resides in the amino-terminal domain of the protein, and the low-affinity NBS-II is localized at 2/3 of the protein sequence. The nucleotide-bound states of soluble SecA were studied by site directed tryptophan fluorescence spectroscopy, tryptic digestion, differential scanning calorimetry, and dynamic light scattering. A nucleotide-induced conformational change of a carboxy-terminal domain of SecA was revealed by Trp fluorescence spectroscopy. The Trp fluorescence of a single Trp SecA mutant containing Trp775 decreased and increased upon the addition of NBS-I saturating concentrations of ADP or AMP-PNP, respectively. DSC measurements revealed that SecA unfolds as a two domain protein. Binding of ADP to NBS-I increased the interaction between the two domains whereas binding of AMP-PNP did not influence this interaction. When both NBS-I and NBS-II are bound by ADP, SecA seems to have a more compact globular conformation whereas binding of AMP-PNP seems to cause a more extended conformation. It is suggested that the compact ADP-bound conformation resembles the membrane deinserted state of SecA, while the more extended ATP-bound conformation may correspond to the membrane inserted form of SecA.

The role of His117 in the redox reactions of azurin from Pseudomonas aeruginosa.

The electron-transfer properties of H117G- and wild-type azurin were compared by applying both as electron acceptors in the conversion of 4-ethylphenol by 4-ethylphenol methylenehydroxylase (4-EPMH). The reactivity of H117G-azurin was determined in the absence and presence of imidazoles, which can substitute the missing fourth ligand. In the absence of imidazoles, H117G-azurin reacted directly with 4-ethylphenol; this reaction was abolished in the presence of imidazoles. The enzymatic reduction of H117G-azurin by 4-EPMH was 40 times slower than that of wild-type azurin. The rate of this reaction was enhanced by some imidazoles, diminished by others. In all cases the reduction of H117G-azurin was irreversible. These results demonstrate that His117 is vital for electron transfer and effectively protects the copper site against aspecific reactions.

Sec-dependent preprotein translocation in bacteria.

Translocation of precursor proteins across the cytoplasmic membrane in bacteria is mediated by a multisubunit protein complex termed translocase, which consists of the integral membrane heterotrimer Sec YEG and the peripheral homodimeric ATPase SecA. Preproteins are bound by the cytosolic molecular chaperone SecB and targeted in a complex with SecA to the translocation site at the cytoplasmic membrane. This interaction with Sec YEG allows the SecA/preprotein complex to insert into the membrane by binding of ATP to the high affinity nucleotide binding site of SecA. At that stage, presumably recognition and proofreading of the signal sequence occurs. Hydrolysis of ATP causes the release of the preprotein in the translocation channel and drives the withdrawal of SecA from the membrane-integrated state. Hydrolysis of ATP at the low-affinity nucleotide binding site of SecA converts the protein into a compact conformational state and releases it from the membrane. In the absence of the proton motive force, SecA is able to complete the translocation stepwise by multiple nucleotide modulated cycles.

Structure of metal site in Cd-substituted His117Gly mutant of azurin with and without addition of imidazole derivatives.

The present work uses 111mCd-perturbed angular correlations of gamma-rays (PAC) to investigate the structure of the metal site of the His117Gly mutant of Pseudomonas aeruginosa azurin in aqueous solution and the effect on the structure upon addition of the following exogenous ligands: imidazole, 4-methyl imidazole, 1-methyl imidazole, 2-methyl imidazole and histidine. The nuclear quadrupole interaction of cadmium bound to the mutant without addition of exogenous ligands shows a strong pH dependence with three different nuclear quadrupole interactions consistent with two pKa values at about 7.2 and 8.6 at 2 degrees C. Addition of the imidazole derivatives resulted in a significant change in the PAC spectrum showing that they coordinate. This is in accordance with observations by EPR for the same mutant with copper at the metal site [den Blaauwen, T. & Canters, G. W. (1993) J. Am. Chem. Soc. 115, 1121-1129]. However, whereas EPR and ultraviolet/visual absorption show that the characteristics of the wild-type copper protein are regained by addition of the imidazole derivatives with the exception of the possible bidentates (histidine and histamine), the comparison of the PAC results to model calculations shows that the cadmium ion must be fourfold coordinated in most cases, probably binding an additional water or hydroxide ligand. A fourfold coordination is in contrast to cadmium-substituted wild-type azurin where PAC data inferred a threefold coordination by a Cys and two His residues [Danielsen, E. Bauer, R., Hemmingsen, L., Andersen. M., Bjerrum, M. J., Butz, T., Tröger, W., Canters, G. W., Hoitink, C. W. G., Karlsson, G., Hansson, O. & Messerschmidt, A. (1995) J. Biol. Chem. 270, 573-580]

Diffusion-limited interaction between unfolded polypeptides and the Escherichia coli chaperone SecB.

SecB is a chaperone dedicated to protein translocation in Escherichia coli. SecB binds to a subset of precursor proteins, and targets them in a translocation-competent state to the SecA subunit of the translocase. The nature and kinetics of the interaction of SecB with polypeptides were studied by spectroscopic techniques using the reduced form of bovine pancreatic trypsin inhibitor (BPTI) as a model substrate. Binding of SecB to BPTI resulted in an increase in the fluorescence of the surface-exposed tryptophan residue 36 of SecB. SecB reversibly binds BPTI in stoichiometric amounts. Labeling of BPTI with the fluorophore acrylodan allowed the analysis of the binding reaction at nanomolar concentrations. High-affinity binding (KD of 5.4 nM) of labeled BPTI to SecB resulted in a blue shift of the acrylodan emission maximum and an increase in the fluorescence quantum yield, suggesting that BPTI binds in an apolar environment. Stopped-flow acquisition of rate constants of complex formation between SecB and BPTI yielded a second-order binding rate constant of 5 x 10(9) M-1 s-1, and a dissociation rate constant of 48 s-1. These data demonstrate that in vitro, the association of SecB with polypeptide substrates is limited by the rate of collision. In vivo, SecB binding is selective, and predominantly occurs with nascent polypeptides. Since these chains are not expected to fold into stable structures, SecB association may be governed by "more or less" specific interactions and be limited by the rate of chain elongation rather than the rate of folding.

Identification of the magnesium-binding domain of the high-affinity ATP-binding site of the Bacillus subtilis and Escherichia coli SecA protein.

The homodimeric SecA protein is the peripheral subunit of the translocase, and couples the hydrolysis of ATP to the translocation of precursor proteins across the bacterial cytoplasmic membrane. The high affinity ATP binding activity of SecA resides in the amino-terminal domain of SecA. This domain contains a tandem repeat of the "so-called" Walker B-motif, hXhhD (Walker, J.E., Saraste, M., Runswick, M.J., and Gay, N.J. (1982) EMBO J. 1, 945-951), that in combination with motif A is responsible for the Mg(2+)-phosphate protein interaction. Two aspartate residues at positions 207 and 215 of the Bacillus subtilis SecA, and Asp-217 in the Escherichia coli SecA, that could be Mg2+ ion ligands, were individually mutated to an asparagine. Mutant SecA proteins were unable to growth-complement an E. coli secA amber mutant strain, and the E. coli SecA mutant interfered with the translocation of precursor proteins in vivo. B. subtilis mutant SecA proteins were expressed to a high level and purified to homogeneity. The high affinity ATP and Mg(2+)-ion binding activity was reduced in the Asp-207 mutant, and completely lost in the Asp-215 mutant. Both SecA proteins were defective in lipid-stimulated ATPase activity. Proteolytic studies suggest that the two subunits of the mutated dimeric SecA proteins are present in different conformational states. These data suggest that Asp-207 and Asp-215 are involved in the binding of the Mg(2+)-ion when Mg(2+)-ATP is bound to SecA, while Asp-207 fulfills an additional catalytic role, possibly in accepting a proton during catalysis.