Specific interactions of quercetin and other flavonoids with target proteins are revealed by elicited fluorescence

The fluorogenic properties of quercetin and similar flavonoids common in plants were exploited to analyse their interaction with target proteins. Quercetin produced a strong fluorescent signal upon binding to bovine serum albumin (BSA) and insulin. The fluorescent signal showed saturation kinetics with increasing flavonoid concentrations indicating the presence of defined peptide binding motifs. Other tested proteins showed no fluorescence with the flavonoids. In a comparative study including 22 flavonoids the compounds with fluorogenic properties were identified using our model proteins BSA and insulin and the structural requirements for the fluorogenic property were defined. Only flavones with a high degree of hydroxylation were able to elicit fluorescence. The emitted fluorescence was strongly enhanced at alkaline pH. Finally, an attempt was made to identify intracellular target molecules in live cells. Drosophila follicles showed a distinct staining pattern thus giving evidence that high concentrations of quercetin binding proteins are present in the nuclei and are associated with the ring canals. The presented biochemical and cytological data show that the interaction of the studied flavonoids with target proteins is specific and this finding opens up new experimental possibilities to systematically identify the cellular proteins with specific binding motifs for quercetin or other fluorogenic compounds of medical interest.     

Specific and nonspecific interactions of integration host factor with oligo DNAs as revealed by circular dichroism spectroscopy and filter binding assay.

Binding specificity of integration host factor (IHF) to oligo DNAs has been studied by circular dichroism (CD) spectroscopy and filter binding experiment. CD difference spectra of IHF-DNA complexes demonstrated that a conformational change in DNA was induced by binding of IHF when DNA had a consensus sequence for the binding sites of IHF, but that such conformational change was not observed for consensus DNA 20 mer as well as nonconsensus DNA 45 mer. Dissociation constants for IHF-DNA complexes determined by filter binding assay showed that IHF has indeed stronger affinity to DNA with the consensus binding site than to nonconsensus DNA, but the difference in its affinity between consensus and nonconsensus DNAs was rather small, 3.4-fold. It was, therefore, concluded that the flanking regions of the consensus sequence are important for the specific binding of IHF and that its binding specificity is well characterized by the induced conformational change in DNA rather than by dissociation constants for IHF-DNA complexes.     

Specific interactions between arbuscular mycorrhizal fungi and plant growth-promoting bacteria: as revealed by different combinations

The interactions between two plant growth-promoting rhizobacteria (PGPR, Pseudomonas fluorescens SBW25 and Paenibacillus brasilensis PB177), two arbuscular mycorrhizal (AM) fungi (Glomus mosseae and Glomus intraradices) and one pathogenic fungus (Microdochium nivale) were investigated on winter wheat (Triticum aestivum cultivar Tarso) in a greenhouse trial. PB177, but not SBW25, had strong inhibitory effects on M. nivale in dual culture plate assays. The results from the greenhouse experiment show very specific interactions; for example, the two AM fungi react differently when interacting with the same bacteria on plants. Glomus intraradices (single inoculation or together with SBW25) increased plant dry weight on M. nivale-infested plants, suggesting that the pathogenic fungus is counteracted by G. intraradices, but PB177 inhibited this positive effect. This is an example of two completely different reactions between the same AM fungus and two species of bacteria, previously known to enhance plant growth and inhibit pathogens. When searching for plant growth-promoting microorganisms, it is therefore important to test for the most suitable combination of plant, bacteria and fungi in order to achieve satisfactory plant growth benefits.     

Actin-fragmin interactions as revealed by chemical cross-linking

A one to one complex of actin and fragmin (a capping protein from Physarum polycephalum plasmodia) was cross-linked with 1-ethyl-3-[3-(dimethylamino)propyl] carbodiimide. The cross-linking reaction generated two cross-linked products with slightly different molecular weights (88 000 and 90 000) as major species. They were cross-linked products of one actin and one fragmin. The cross-linking site of fragmin in the actin sequence was determined by peptide mappings [Sutoh, K. (1982) Biochemistry 21, 3654-3661] after partial chemical cleavages of cross-linked products with hydroxylamine. The results indicated that the N-terminal segment of actin spanning residues 1-12 participated in cross-linking with fragmin. The cross-linker used in this study covalently bridges lysine side chains and side chains of acidic residues when they are in direct contact. Therefore, it seems that acidic residues in the N-terminal segment of actin (Asp-1, Glu-2, Asp-3, Glu-4, and Asp-11), at least some of them, are in the binding site of fragmin. It has already been shown that the same acidic segment of actin is in the binding site of myosin or depactin (an actin-depolymerizing protein isolated from starfish oocytes). We suggest that the unusual amino acid sequence of the N-terminal segment of actin makes its N-terminal region a favorable anchoring site for various types of actin-binding proteins.     

Specific and selective peptide-membrane interactions revealed using quartz crystal microbalance

The skin secretions of Australian tree frogs are rich in peptides with potential antimicrobial activity. They interrupt bacterial cell membranes, although precisely how and whether all peptides have the same mechanism is not known. The interactions of three of these peptides—aurein 1.2, maculatin 1.1, and caerin 1.1 with supported phospholipid bilayers—are examined here using quartz crystal microbalance and atomic force microscopy. These approaches enabled us to reveal variations in material structure and density as a function of distance from the sensor surface when comparing mass sensorgrams over a range of harmonics of the natural resonance of the sensor crystal and hence obtain for the first time to our knowledge a mechanistic assessment of membrane disruption. We found that caerin inserted into the bilayer in a transmembrane manner, regardless of concentration and phospholipid composition consistent with a pore-forming mechanism. In contrast, maculatin and aurein interacted with membranes in a concentration-dependent manner. At low concentrations (<5 μM), maculatin exhibited transmembrane incorporation whereas aurein was limited to surface association. Upon reaching a threshold value of concentration, both peptides lysed the membrane. In the case of maculatin, the lysis progressed in a slow, concentration-dependent manner, forming mixed micelles, as shown by atomic force microscopy imaging. Aurein-induced lysis proceeded to a sudden disruption, which is consistent with the “carpet” mechanism. Both maculatin and aurein exhibit specificity toward phospholipids and thus have potential as candidates as antimicrobial drugs.     

The structure and thermotropism of thymocyte plasma membranes as revealed by laser-raman spectroscopy.

1. Plasma membranes from rabbit thymocytes have been analyzed by laser-Raman spectroscopy over the 800-3000 cm-1 region and the spectra compared with those of endoplasmic reticulum, as well as relevant liposome systems. 2. Evaluation of the Amide I and Amide III regions indicates that thymocyte plasma membranes, but not endoplasmic reticulum, contain appreciable beta-structure peptide. This conclusion is supported by infrared spectroscopy. 3. Evaluation of the 2890 cm-1: 2850 cm-1 intensity ratio of plasma membranes as a function of temperature, using an integration technique, demonstrates a thermotropic lipid transition centered near 23 degrees C. This transition is less sharp than one observed with egg lecithin in this temperature range. 4. The significance of the thermotropic transition is evaluated in view of the lack of thermotropic lipid-protein segregation detectable by freeze-fracture electron microscopy (Wunderlich, F., Wallach, D.F.H., Speth, V. and Fischer, H. (1973) Biochim. Biophys. Acta 373, 34-43).     

Histone-histone interactions as revealed by formaldehyde treatment of chromatin

Histone oligomers produced by formaldehyde treatment of chromatin were studied. It was shown that these histone oligomers could be converted into monomers by boiling in 0.1 NH₂SO₄. Dimers H2B-H4 and H2B-H2A were identified by two-dimensional polyacrylamide gel electrophoresis.Abbreviations. Histones Nomenclature H1 formerly histone F1 - H2B formerly histone F2b - H2A formerly histone F2a2 - H3 formerly histone F3 - H4 formerly histone F2a1 This nomenclature has been proposed at the recent Symposium on the Structure and Function of Chromatin. Ciba Foundation. London. April 1974.     

Interaction of epicatechin gallate with phospholipid membranes as revealed by solid-state NMR spectroscopy

Epicatechin gallate (ECg), a green tea polyphenol, has various physiological effects. Our previous nuclear Overhauser effect spectroscopy (NOESY) study using solution NMR spectroscopy demonstrated that ECg strongly interacts with the surface of phospholipid bilayers. However, the dynamic behavior of ECg in the phospholipid bilayers has not been clarified, especially the dynamics and molecular arrangement of the galloyl moiety, which supposedly has an important interactive role. In this study, we synthesized [13C]-ECg, in which the carbonyl carbon of the galloyl moiety was labeled by 13C isotope, and analyzed it by solid-state NMR spectroscopy. Solid-state 31P NMR analysis indicated that ECg changes the gel-to-liquid-crystalline phase transition temperature of DMPC bilayers as well as the dynamics and mobility of the phospholipids. In the solid-state 13C NMR analysis under static conditions, the carbonyl carbon signal of the [13C]-ECg exhibited an axially symmetric powder pattern. This indicates that the ECg molecules rotate about an axis tilting at a constant angle to the bilayer normal. The accurate intermolecular-interatomic distance between the labeled carbonyl carbon of [13C]-ECg and the phosphorus of the phospholipid was determined to be 5.3±0.1 ? by 13C-(31)P rotational echo double resonance (REDOR) measurements. These results suggest that the galloyl moiety contributes to increasing the hydrophobicity of catechin molecules, and consequently to high affinity of galloyl-type catechins for phospholipid membranes, as well as to stabilization of catechin molecules in the phospholipid membranes by cation-π interaction between the galloyl ring and quaternary amine of the phospholipid head-group.     

Specific interactions of sticholysin I with model membranes: An NMR study

Sticholysin I (StnI) is an actinoporin produced by the sea anemone Stichodactyla helianthus that binds biological and model membranes forming oligomeric pores. Both a surface cluster of aromatic rings and the N‐terminal region are involved in pore formation. To characterize the membrane binding by StnI, we have studied by ¹H‐NMR the environment of these regions in water and in the presence of membrane‐mimicking micelles. Unlike other peptides from homologous actinoporins, the synthetic peptide corresponding to residues 1–30 tends to form helix in water and is more helical in either trifluoroethanol or dodecylphosphocholine (DPC) micelles. In these environments, it forms a helix‐turn‐helix motif with the last α‐helical segment matching the native helix‐α₁ (residues 14–24) present in the complete protein. The first helix (residues 4–9) is less populated and is not present in the water‐soluble protein structure. The characterization of wild‐type StnI structure in micelles shows that the helix‐α₁ is maintained in its native structure and that this micellar environment does not provoke its detachment from the protein core. Finally, the study of the aromatic resonances has shown that the motional flexibility of specific rings is perturbed in the presence of micelles. On these bases, the implication of the aromatic rings of Trp‐111, Tyr‐112, Trp‐115, Tyr‐132, Tyr‐136, and Tyr‐137, in the interaction between StnI and the micelle is discussed. Based on all the findings, a revised model for StnI interaction with membranes is proposed, which accounts for differences in its behavior as compared with other highly homologous sticholysins. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Insights on the interactions of synthetic amphipathic peptides with model membranes as revealed by 31P and 2H solid-state NMR and infrared spectroscopies

We studied the interaction between synthetic amphipathic peptides and model membranes by solid-state NMR and infrared spectroscopies. Peptides with 14 and 21 amino acids composed of leucines and phenylalanines modified by the addition of crown ethers were synthesized. The 14-mer and 21-mer peptides both possess a helical amphipathic structure. To shed light on their membrane interaction, (31)P and (2)H solid-state NMR experiments were performed on both peptides in interaction with dimyristoylphosphatidylcholine vesicles in the absence and presence of cholesterol, dimyristoylphosphatidylglycerol vesicles, and oriented bicelles. (31)P NMR experiments on multilamellar vesicles reveal that the dynamics and/or orientation of the polar headgroups are weakly yet markedly affected by the presence of the peptides, whereas (31)P NMR experiments on bicelles indicate no significant changes in the morphology and orientation of the bicelles. On the other hand, (2)H NMR experiments on vesicles reveal that the acyl chain order is affected differently depending on the membrane lipidic composition and on the peptide hydrophobic length. Finally, infrared spectroscopy was used to study the interfacial region of the bilayer. Based on these studies, mechanisms of membrane perturbation are proposed for the 14-mer and 21-mer peptides in interaction with model membranes depending on the bilayer composition and peptide length.     

Protein folding and interactions revealed by mass spectrometry.

Mass spectrometry is capable of examining very large, dynamic proteins and this ability, coupled with its relatively high throughput and low sample requirements, is reflected by its increasing importance for the characterisation of protein structure. Recent developments in mass spectrometry, in particular the refinement of the electrospray process and its coupling with time-of-flight mass analysis, mean that it is poised to contribute not only as a complementary tool but also with a defined role in many areas of chemical biology.     

Interactions of bilirubin and other ligands with ligandin.

Circular dichroism methods were used to study the structure of rat ligandin and the binding of organic anions to the protein. Ligandin has a highly ordered secondary structure with about 40%alpha helix, 15% beta structure, and 45% random coil. Bilirubin binding occurred primarily at a single high affinity site on the protein. The binding constant for bilirubin (5 X 10-7 Mminus 1) was the highest among the ligands studied. The bilirubin-ligandin complex exhibited a well-defined circular dichroic spectrum with two major overlapping ellipticity bands of opposite sign in the bilirubin absorption region. This spectrum was virtually a mirror image of that of human or rat serum albumin-bilirubin complexes. Studies on the direct transfer of bilirubin from ligandin to rat serum albumin showed that sasociation constants of bilirubin-ligandin complexes were approximately tenfold less than those of the bilirubin-albumin system. Ligandin exhibited a broad specificity with respect to the typeof ligand bond. A series of organic anions inclucing dyes used clinically for liver function tests, fatty acids, hormones, heme derivatives, bile acids, and other ligands that were considered likely to interact with ligandin, were examined. Most induced ellipticity changes consistent with competitive displacement of bilirubin from ligandin and relative affinities of these compounds for ligandin were determined based on their effectiveness in desplacing the bilirubin. Some substances such as glutathione, conjugated sulfobromophthaleins and lithocholic acid bound to ligandin but induced anomalous spectral shifts, when added to ligandin-bilirubin complexes. Other compounds, including some that act as substrates for the glutathione transferase activity exhibited by ligandin, revealed no apparent competitive effects with respect to the bilitubin binding site.     

Molecular interactions of adenosine triphosphatase with the mitochondrial membrane as revealed by a spin label study.

Mitochondrial ATPase complex has been spin-labeled in the membrane using the inhibitor N-(2,2,6,6-tetramethylpeperidyl-1-OXYL)-N(cyclohexyl)carbodiimide (nccd). the amount of NCCD bound to mitochondrial fragments is 0.5 nmol/mg and cannot be dialyzed or extracted with ether, chloroform, or methanol. The electron paramagnetic resonance spectrum of NCCD bound to fragments is pH-sensitive, a greater label immobilization occurring at pH values lower or higher than 7. Ether extraction removes the ATPase inhibition by NCCD without detaching the label. This effect appears to be the consequence of the dislocation of some components of the ATPase complex. Removal of F1 natural inhibitor or of F1 does not affect the spectrum of NCCD bound to fragments, while the removal of oligomycin sensitivity-conferring protein produces an increase in the extreme splitting. Oligomycin sensitivity-conferring protein may thus interact with the NCCD binding component of the membrane. The isolation of the NCCD-binding proteolipid results in a large increase in the mobility of the label, but addition of dipalmitoyllecithin decreases the mobility of the label to the original level. Phospholipids are thus necessary to keep the NCCD-binding proteolipid in the native conformation.     

Heterotropic interactions of ligands with phosphorylase b.

1. The interaction of rabbit muscle glycogen phosphorylase b with pairs of ligands has been examined. 2. The electron spin resonance spectrum of a spin label, covalently attached to the protein, provided information about dissociation constants, formation of ternary complexes and both negative and positive interactions between different ligand pairs. 3. AMP competes with a series of nucleotides (ADP, ATP, CMP aand cytosine) but with adenosine a ternary enzyme - AMP - adenosine complex can be formed. 4. ADP binding is tight and ADP inhibits the AMP activation of phosphorylase b in a physiologically important concentration range. 5. The substrates glucose 1-phosphate and glycogen tighten AMP binding in the ternary complex as does the competitive inhibitor UDPG. Inorganic phosphate is different in this respect. Gluconolactone, a transition state analogue, competes with glucose 1-phosphate (but not with glycogen) but does not prevent completely the binding of the sugar phosphate. 6. The effect of glucose b-phosphate on phosphorylase is rather complex as it 'formally competes' with both AMP and UDPG probably mediated by a conformational changes and not by 'direct' interactions with these two ligands. Glycerol 2-phosphate, a commonly used buffer for phosphorylase, also shows complex interactions.     

Cholesterol interactions with phospholipids in membranes.

Mammalian cell membranes are composed of a complex array of glycerophospholipids and sphingolipids that vary in head-group and acyl-chain composition. In a given cell type, membrane phospholipids may amount to more than a thousand molecular species. The complexity of phospholipid and sphingolipid structures is most likely a consequence of their diverse roles in membrane dynamics, protein regulation, signal transduction and secretion. This review is mainly focused on two of the major classes of membrane phospholipids in eukaryotic organisms, sphingomyelins and phosphatidylcholines. These phospholipid classes constitute more than 50% of membrane phospholipids. Cholesterol is most likely to associate with these lipids in the membranes of the cells. We discuss the synthesis and distribution in the cell of these lipids, how they are believed to interact with each other, and what cellular consequences such interactions may have. We also include a discussion about findings in the recent literature regarding cholesterol/phospholipid interactions in model membrane systems. Finally, we look at the recent trends in computer and molecular dynamics simulations regarding phospholipid and cholesterol/phospholipid behavior in bilayer membranes.