Evidence for a fluorescence yield change driven by a light-induced conformational change within photosystem II during the fast chlorophyll a fluorescence rise

Experiments were carried out to identify a process co-determining with Q(A) the fluorescence rise between F(0) and F(M). With 3-(3',4'-dichlorophenyl)-1,1-dimethylurea (DCMU), the fluorescence rise is sigmoidal, in its absence it is not. Lowering the temperature to -10°C the sigmoidicity is lost. It is shown that the sigmoidicity is due to the kinetic overlap between the reduction kinetics of Q(A) and a second process; an overlap that disappears at low temperature because the temperature dependences of the two processes differ. This second process can still relax at -60°C where recombination between Q(A)(-) and the donor side of photosystem (PS) II is blocked. This suggests that it is not a redox reaction but a conformational change can explain the data. Without DCMU, a reduced photosynthetic electron transport chain (ETC) is a pre-condition for reaching the F(M). About 40% of the variable fluorescence relaxes in 100ms. Re-induction while the ETC is still reduced takes a few ms and this is a photochemical process. The fact that the process can relax and be re-induced in the absence of changes in the redox state of the plastoquinone (PQ) pool implies that it is unrelated to the Q(B)-occupancy state and PQ-pool quenching. In both +/-DCMU the process studied represents ~30% of the fluorescence rise. The presented observations are best described within a conformational protein relaxation concept. In untreated leaves we assume that conformational changes are only induced when Q(A) is reduced and relax rapidly on re-oxidation. This would explain the relationship between the fluorescence rise and the ETC-reduction.     

Ligand-induced conformational change in the ferrichrome–iron receptor of Escherichia coli K-12

Ferrichrome–iron is actively transported across the outer membrane of Escherichia coli by the TonB-dependent receptor FhuA. To obtain FhuA in a form suitable for secondary-structure analyses, a hexahistidine tag was inserted into a surface-located site and the recombinant protein was purified by metal chelate chromatography. Functional studies indicated that the presence of the hexahistidine tag did not interfere with FhuA localization or with ligand-binding activity. Ferrichrome protected lysine 67 but not lysine 5 of purified recombinant FhuA from trypsinolysis. Results from trypsin digestion were interpreted as a conformational change in FhuA which had occurred upon ferrichrome binding, thereby preventing access of trypsin to lysine 67. Circular dichroism and Fourier transform infrared spectroscopy revealed a predominance of -sheet structure for the purified protein. In the presence of ferrichrome, FhuA exhibited a secondary structure and a thermostability which were similar to FhuA without ligand. The addition of ferrichrome to purified FhuA reduced the ability of certain anti-FhuA monoclonal antibodies to bind to the receptor. All antibodies which could in this manner discriminate between FhuA and FhuA bound to ferrichrome had their determinants within a loop which is toward the N-terminus and which is exposed to the periplasm. These data indicate that the binding of ferrichrome induces a structural change that is propogated across the outer membrane and results in an altered conformation of a periplasmically exposed loop of FhuA. It is proposed that by such an alteration of FhuA conformation, TonB is triggered to energize the active transport of the bound ligand across the outer membrane.     

Evidence for multiple pathways in the assembly of the Escherichia coli maltose transport complex

We used the maltose transport complex MalFGK2 of the Escherichia coli cytoplasmic membrane as a model for the study of the assembly of hetero-oligomeric membrane protein complexes. Analysis of other membrane protein complexes has led to a general model in which a unique, ordered pathway is followed from subunit monomers to a final oligomeric structure. In contrast, the studies reported here point to a fundamentally different mode for assembly of this transporter. Using co-immunoprecipitation and quantification of interacting partners, we found that all subunits of the maltose transport complex efficiently form heteromeric complexes in vivo. The pairwise complexes were stable over time, suggesting that they all represent assembly intermediates for the final MalFGK2 transporter. These results indicate that several paths can lead to assembly of this oligomer. We also characterized MalF and MalG mutants that caused reduced association between some or all of the subunits of the complex with this assay. The mutant analysis highlights some important motifs for subunit contacts and suggests that the promiscuous interactions between these Mal proteins contribute to the efficiency of complex assembly. The behaviors of the wild type and mutant proteins in the co-immunoprecipitations support a model of multiple assembly pathways for this complex.     

Dissociation of intact Escherichia coli ribosomes in a mass spectrometer. Evidence for conformational change in a ribosome elongation factor G complex

We used mass spectrometry to identify proteins that are released in the gas phase from Escherichia coli ribosomes in response to a range of different solution conditions and cofactor binding. From solution at neutral pH the spectra are dominated by just 4 of the 54 ribosomal proteins (L7/L12, L11, and L10). Lowering the pH of the solution leads to the gas phase dissociation of four additional proteins as well as the 5 S RNA. Replacement of Mg(2+) by Li(+) ions in solutions of ribosomes induced the dissociation of 17 ribosomal proteins. Correlation of these results with available structural information for ribosomes revealed that a relatively high interaction surface area of the protein with RNA was the major force in preventing dissociation. By using the proteins that dissociate to probe their interactions with RNA, we examined different complexes of the ribosome formed with the elongation factor G and inhibited by fusidic acid or thiostrepton. Mass spectra recorded for the fusidic acid-inhibited complex reveal subtle changes in peak intensity of the proteins that dissociate. By contrast gas phase dissociation from the thiostrepton-inhibited complex is markedly different and demonstrates the presence of L5 and L18, two proteins that interact exclusively with the 5 S RNA. These results allow us to propose that the ribosome elongation factor-G complex inhibited by thiostrepton, but not fusidic acid, involves destabilization of 5 S RNA-protein interactions.     

Osmoregulation of the maltose regulon in Escherichia coli.

The maltose regulon consists of four operons that direct the synthesis of proteins required for the transport and metabolism of maltose and maltodextrins. Expression of the mal genes is induced by maltose and maltodextrins and is dependent on a specific positive regulator, the MalT protein, as well as on the cyclic AMP-catabolite gene activator protein complex. In the absence of an exogenous inducer, expression of the mal regulon was greatly reduced when the osmolarity of the growth medium was high; maltose-induced expression was not affected, and malTc-dependent expression was only weakly affected. Mutants lacking MalK, a cytoplasmic membrane protein required for maltose transport, expressed the remaining mal genes at a high level, presumably because an internal inducer of the mal system accumulated; this expression was also strongly repressed at high osmolarity. The repression of mal regulon expression at high osmolarity was not caused by reduced expression of the malT, envZ, or crp gene or by changes in cellular cyclic AMP levels. In strains carrying mutations in genes encoding amylomaltase (malQ), maltodextrin phosphorylase (malP), amylase (malS), or glycogen (glg), malK mutations still led to elevated expression at low osmolarity. The repression at high osmolarity no longer occurred in malQ mutants, however, provided that glycogen was present.     

Role of the receptor for bacteriophage lambda in the functioning of the maltose chemoreceptor of Escherichia coli.

Chemotaxis towards maltose is specifically defective in many strains of Escherichia coli carrying mutations affecting lamB, the gene coding for the outer membrane receptor for bacteriophage lambda. However, with one exception, the most extreme effect of lamB mutants on the maltose response as determined in the capillary assay is a shift to higher sugar concentrations and a reduction in the number of bacteria accumulated to about 25% of the wild-type level. The severity of the taxis defect is strongly correlated with reduced ability of the cells to take up the maltose present at 1 and 10 muM. Evidence presented here and in the accompanying paper indicates that the lambda receptor is involved in the transport of maltose at these concentrations. The effects of lamB mutations on maltose taxis can be explained by postulating that the high-affinity maltose transport system in which the lambda receptor participates transfers maltose from the surrounding medium across the outer membrane and into the periplasmic space. If the maltose chemoreceptor detects sugar present in the periplasmic space, and not molecules external to the outer membrane, then defective transport of low concentrations of maltose into the periplasm would result in the observed apparent reduction in the sensitivity of the maltose receptor. Thus, the lambda receptor protein would participate in maltose chemorecepton only indirectly through its role in maltose transport.     

Evidence for RNA in the peptidyl transferase center of Escherichia coli ribosomes as indicated by fluorescence.

A coumarin derivative was covalently attached to either the amino acid or the 5' end of phenylalanine-specific transfer RNA (tRNA(phe)). Its fluorescence was quenched by methyl viologen when the tRNA was free in solution or bound to Escherichia coli ribosomes. Methyl viologen as a cation in solution has a strong affinity for the ionized phosphates of a nucleic acid and so can be used to qualitatively measure the presence of RNA in the immediate vicinity of the tRNA-linked coumarins upon binding to ribosomes. Fluorescence lifetime measurements indicate that the increase in fluorescence quenching observed when the tRNAs are bound into the peptidyl site of ribosomes is due to static quenching by methyl viologen bound to RNA in the immediate vicinity of the fluorophore. The data lead to the conclusion that the ribosome peptidyl transferase center is rich in ribosomal RNA. Movement of the fluorophore at the N-terminus of the nascent peptide as it is extended or movement of the tRNA acceptor stem away from the peptidyl transferase center during peptide bond formation appears to result in movement of the probe into a region containing less rRNA.     

Evidence for a phosphorylation-induced conformational change in phospholamban cytoplasmic domain by CD analysis.

Phospholamban (PLB), an integral membrane protein of cardiac sarcoplasmic reticulum (SR), is described as the regulator of the Ca(2+)-ATPase pump, via its phosphorylation-dephosphorylation of Ser-16. Recently it has been shown that a direct interaction between the N-terminal hydrophilic domain of PLB and Ca(2+)-ATPase may be one of the mechanisms of regulation. In order to show that this interaction could be modulated by a phosphorylation-induced conformational change in PLB, we ran CD studies on the synthetic peptide PLB(2-33) in its phosphorylated and non-phosphorylated forms, at various pHs, concentrations and in the absence or presence of trifluoroethanol. The results show a clear difference in structure of the phosphorylated and non-phosphorylated peptide.     

Role of maltose enzymes in glycogen synthesis by Escherichia coli

Mutants with deletion mutations in the glg and mal gene clusters of Escherichia coli MC4100 were used to gain insight into glycogen and maltodextrin metabolism. Glycogen content, molecular mass, and branch chain distribution were analyzed in the wild type and in ΔmalP (encoding maltodextrin phosphorylase), ΔmalQ (encoding amylomaltase), ΔglgA (encoding glycogen synthase), and ΔglgA ΔmalP derivatives. The wild type showed increasing amounts of glycogen when grown on glucose, maltose, or maltodextrin. When strains were grown on maltose, the glycogen content was 20 times higher in the ΔmalP strain (0.97 mg/mg protein) than in the wild type (0.05 mg/mg protein). When strains were grown on glucose, the ΔmalP strain and the wild type had similar glycogen contents (0.04 mg/mg and 0.03 mg/mg protein, respectively). The ΔmalQ mutant did not grow on maltose but showed wild-type amounts of glycogen when grown on glucose, demonstrating the exclusive function of GlgA for glycogen synthesis in the absence of maltose metabolism. No glycogen was found in the ΔglgA and ΔglgA ΔmalP strains grown on glucose, but substantial amounts (0.18 and 1.0 mg/mg protein, respectively) were found when they were grown on maltodextrin. This demonstrates that the action of MalQ on maltose or maltodextrin can lead to the formation of glycogen and that MalP controls (inhibits) this pathway. In vitro, MalQ in the presence of GlgB (a branching enzyme) was able to form glycogen from maltose or linear maltodextrins. We propose a model of maltodextrin utilization for the formation of glycogen in the absence of glycogen synthase.     

New maltose Blu mutations in Escherichia coli K-12.

Mutations in the genes pgi, pfkA, and ptsG resulted in a maltose Blu phenotype in Escherichia coli K-12, bringing the number of known Blu alleles to six. The Blu phenotype, as visualized by staining with iodine vapor, is a convenient mutant isolation technique.     

FtsZ polymer-bundling by the Escherichia coli ZapA orthologue, YgfE, involves a conformational change in bound GTP

Cell division is a fundamental process for both eukaryotic and prokaryotic cells. In bacteria, cell division is driven by a dynamic, ring-shaped, cytoskeletal element (the Z-ring) made up of polymers of the tubulin-like protein FtsZ. It is thought that lateral associations between FtsZ polymers are important for function of the Z-ring in vivo, and that these interactions are regulated by accessory cell division proteins such as ZipA, EzrA and ZapA. We demonstrate that the putative Escherichia coli ZapA orthologue, YgfE, exists in a dimer/tetramer equilibrium in solution, binds to FtsZ polymers, strongly promotes FtsZ polymer bundling and is a potent inhibitor of the FtsZ GTPase activity. We use linear dichroism, a technique that allows structure analysis of molecules within linear polymers, to reveal a specific conformational change in GTP bound to FtsZ polymers, upon bundling by YgfE. We show that the consequences of FtsZ polymer bundling by YgfE and divalent cations are very similar in terms of GTPase activity, bundle morphology and GTP orientation and therefore propose that this conformational change in bound GTP reveals a general mechanism of FtsZ bundling.     

Ligand interactions and protein conformational changes of phosphopyridoxyl-labeled Escherichia coli phosphoenolpyruvate carboxykinase determined by fluorescence spectroscopy.

Escherichia coli phosphoenolpyruvate (PEP) carboxykinase catalyzes the decarboxylation of oxaloacetate and transfer of the gamma-phosphoryl group of ATP to yield PEP, ADP, and CO2. The interaction of the enzyme with the substrates originates important domain movements in the protein. In this work, the interaction of several substrates and ligands with E. coli PEP carboxykinase has been studied in the phosphopyridoxyl (P-pyridoxyl)-enzyme adduct. The derivatized enzyme retained the substrate-binding characteristics of the native protein, allowing the determination of several protein-ligand dissociation constants, as well as the role of Mg2+ and Mn2+ in substrate binding. The binding affinity of PEP to the enzyme-Mn2+ complex was -8.9 kcal.mol-1, which is 3.2 kcal.mol-1 more favorable than in the complex with Mg2+. For the substrate nucleotide-metal complexes, similar binding affinities (-6.0 to -6.2 kcal.mol-1) were found for either metal ion. The fluorescence decay of the P-pyridoxyl group fitted to two lifetimes of 5.15 ns (34%) and 1.2 ns. These lifetimes were markedly altered in the derivatized enzyme-PEP-Mn complexes, and smaller changes were obtained in the presence of other substrates. Molecular models of the P-pyridoxyl-E. coli PEP carboxykinase showed different degrees of solvent-exposed surfaces for the P-pyridoxyl group in the open (substrate-free) and closed (substrate-bound) forms, which are consistent with acrylamide quenching experiments, and suggest that the fluorescence changes reflect the domain movements of the protein in solution.     

A conformational change in the lactose permease of Escherichia coli is induced by ligand binding or membrane potential.

Lactose transport in membrane vesicles containing lactose permease with a single Cys residue in place of Val 315 is inactivated by N-ethylmaleimide in a manner that is stimulated by substrate or by a H+ electrochemical gradient (delta microH+; Sahin-Tóth M, Kaback HR, 1993, Protein Sci 2:1024-1033). The findings are confirmed and extended in this communication. Purified, reconstituted Val 315-->Cys permease reacts with N-ethylmaleimide or hydrophobic fluorescent maleimides but not with a membrane impermeant thiol reagent, and beta-galactosides specifically stimulate the rate of labeling. Furthermore, the reactivity of purified Val 315-->Cys permease is enhanced by imposition of a membrane potential (delta psi, interior negative). The results indicate that either ligand binding or delta psi induces a conformational change in the permease that brings the N-terminus of helix X into an environment that is more accessible from the lipid phase.