Albumin stabilizes (-)-epigallocatechin gallate in human serum: binding capacity and antioxidant property.

(-)-Epigallocatechin gallate (EGCg) is the major component of green tea and is known to show strong biological activity, although it can be easily oxidized under physiological conditions. In this study, we indicate that EGCg is stable in human serum and that human serum albumin (HSA) stabilizes EGCg under aerobic condition. Although EGCg is usually decomposed within 1 h in aqueous solution at neutral pH, EGCg in serum and phosphate buffer (pH 7.4) containing HSA was stable over 1 h, even at neutral and slightly alkaline pH. Under these conditions, EGCg binds to HSA non-covalently. The sulfhydryl group acts as an antioxidant for EGCg oxidation. Incubation of EGCg with HSA is accompanied by the oxidation of a free sulfhydryl group in HSA. These results suggest that the antioxidant property and the binding capacity of HSA contribute to the stabilization of EGCg in human serum.

Interaction of tea catechins with lipid bilayers investigated by a quartz-crystal microbalance analysis.

The quartz-crystal microbalance (QCM) technique was applied to investigate the interaction of tea catechins with lipid bilayers. The association constants obtained from the frequency changes of QCM revealed that (-)epicatechin gallate and (-)epigallocatechin gallate interacted with 1,2-dimyristoyl-sn-glycero-3-phosphocholine ca. 1000 times more strongly than (-)epicatechin and (-)epigallocatechin. The results exhibited good correlation with the strength of biological activity.

Dynamic behavior of tea catechins interacting with lipid membranes as determined by NMR spectroscopy.

Interaction between tea catechins, such as epicatechin gallate (ECg) and epigallocatechin gallate (EGCg), and isotropic bicelle model lipid membranes was investigated by solution NMR techniques. (1)H NMR measurements provided signals from the B-ring and the galloyl moiety in ECg and EGCg that were obviously shifted, and whose proton T1 relaxation times were shortened upon interaction of the catechins with the bicelles. These results indicate that the B-ring and the galloyl moiety play an important role in this interaction. Nuclear Overhauser effect spectrometry experiments demonstrated that the B-ring and the galloyl moiety are located near the gamma-H in the phospholipid trimethylammonium group. On the basis of these findings, we propose that ECg and EGCg interact with the surface of lipid membranes via the choline moiety.

Suppression of tumor-induced angiogenesis by Brazilian propolis: major component artepillin C inhibits in vitro tube formation and endothelial cell proliferation.

Propolis, a resinous substance collected by honeybees from various plant sources, possesses various physiological activities such as antitumor effects. We have previously shown that propolis of Brazilian origin was composed mainly of artepillin C and that its constituents were quite different from those of propolis of European origin. In this report, we examined an antiangiogenic effects of Brazilian propolis and investigated whether artepillin C was responsible for such effects. In an in vivo angiogenesis assay using ICR mice, we found that the ethanol extract of Brazilian propolis (EEBP) significantly reduced the number of newly formed vessels. EEBP also showed antiangiogenic effects in an in vitro tube formation assay. When compared with other constituents of EEBP, only artepillin C was found to significantly inhibit the tube formation of HUVECs in a concentration-dependent manner (3.13-50microg/ml). In addition, artepillin C significantly suppressed the proliferation of HUVECs in a concentration-dependent manner (3.13-50microg/ml). Furthermore, artepillin C significantly reduced the number of newly formed vessels in an in vivo angiogenesis assay. Judging from its antiangiogenic activity in vitro and in vivo, we concluded that artepillin C at least in part is responsible for the antiangiogenic activity of EEBP in vivo. Artepillin C may prove useful in the development of agents and foods with therapeutic or preventive activity against tumor angiogenesis.

Changes in the mutagenic and estrogenic activities of 17beta-estradiol after treatment with nitrite.

We determined the changes in the mutagenic and estrogenic activities of 17beta-estradiol after a nitrite treatment. Nitrite-treated 17beta-estradiol showed mutagenic activities toward Salmonella typhimurium strains TA 100 and TA 98. We confirmed that nitrite-treated 17beta-estradiol generated radicals from the results of an analysis of electron spin resonance. By applying an instrumental analysis, we identified 2-nitro-17beta-estradiol to have been formed in the reaction mixture. 2-Nitro-17beta-estradiol did not exhibit mutagenic activities toward Salmonella typhimurium strains, suggesting that other mutagens might have been formed in the reaction mixture. The clastogenic properties of nitrite-treated 17beta-estradiol and 2-nitro-17beta-estradiol were analyzed by a micronucleus test with male ICR mice. Nitrite-treated 17beta-estradiol and 2-nitro-17beta-estradiol induced a significantly higher frequency of micronucleated reticulocytes in mice. The estrogenic activity of 2-nitro-17beta-estradiol was found to be lower than that of 17beta-estradiol. These data suggest that a daily oral intake of 17beta-estradiol and nitrite might induce the formation of mutagenic compounds in our body.

Functionally relevant coupled dynamic profile of bacteriorhodopsin and lipids in purple membranes.

The dynamics of bacteriorhodopsin (bR) and the lipid headgroups in oriented purple membranes (PMs) was determined at various temperatures and relative humidity (rh) using solid-state NMR spectroscopy. The 31P NMR spectra of the alpha- and gamma-phosphate groups in methyl phosphatidylglycerophosphate (PGP-Me), which is the major phospholipid in the PM, changed sensitively with hydration levels. Between 253 and 233 K, the signals from a fully hydrated sample became broadened similarly to those of a dry sample at 293 K. The 15N cross polarization (CP) NMR spectral intensities from [15N]Gly bR incorporated into fully hydrated PMs were suppressed in 15N CP NMR spectra at 293 K compared with those of dry membranes but gradually recovered at low temperatures or at lower hydration (75%) levels. The suppression of the NMR signals, which is due to interference with proton decoupling frequency (approximately 45 kHz), coupled with short spin-spin relaxation times (T2) indicates that the loops of bR, in particular, have motional components around this frequency. The motion of the transmembrane alpha-helices in bR was largely affected by the freezing of excess water at low temperatures. While between 253 and 233 K, where a dynamic phase transition-like change was observed in the 31P NMR spectra for the phosphate lipid headgroups, the molecular motion of the loops and the C- and N-termini slowed, suggesting lipid-loop interactions, although protein-protein interactions between stacks cannot be excluded. The results of T2 measurements of dry samples, which do not have proton pumping activity, were similar to those for fully hydrated samples below 213 K where the M-intermediates can be trapped. These results suggest that motions in the 10s micros correlation regime may be functionally important for the photocycle of bR, and protein-lipid interactions are motionally coupled in this dynamic regime.

Differential stiffness and lipid mobility in the leaflets of purple membranes.

Purple membranes (PM) are two-dimensional crystals formed by bacteriorhodopsin and a variety of lipids. The lipid composition and density in the cytoplasmic (CP) leaflet differ from those of the extracellular (EC) leaflet. A new way of differentiating the two sides of such asymmetric membranes using the phase signal in alternate contact atomic force microscopy is presented. This method does not require molecular resolution and is applied to study the stiffness and intertrimer lipid mobility in both leaflets of the PM independently over a broad range of pH and salt concentrations. PM stiffens with increasing salt concentration according to two different regimes. At low salt concentration, the membrane Young's normal modulus grows quickly but differentially for the EC and CP leaflets. At higher salt concentration, both leaflets behave similarly and their stiffness converges toward the native environment value. Changes in pH do not affect PM stiffness; however, the crystal assembly is less pronounced at pH > or = 10. Lipid mobility is high in the CP leaflet, especially at low salt concentration, but negligible in the EC leaflet regardless of pH or salt concentration. An independent lipid mobility study by solid-state NMR confirms and quantifies the atomic force microscopy qualitative observations.

Structural and orientational constraints of bacteriorhodopsin in purple membranes determined by oriented-sample solid-state NMR spectroscopy.

We report for the first time, oriented-sample solid-state NMR experiments, specifically polarization inversion spin exchange at the magic angle (PISEMA) and 1H-15N heteronuclear chemical shift correlation (HETCOR), applied to an integral seven-transmembrane protein, bacteriorhodopsin (bR), in natural membranes. The spectra of [15N]Met-bR revealed clearly distinguishable signals from the helical and loop regions. By deconvolution of the helix resonances, it was possible to establish constraints for some helix tilt angles. It was estimated that the extracellular section of helix B has a tilt of less than 5 degrees from the membrane normal, while the tilt of helix A was estimated to be 18-22 degrees , both of which are in agreement with most crystal structures. Comparison of the experimental PISEMA spectrum with simulated spectra based on crystal structures showed that PISEMA and HETCOR experiments are extremely sensitive to the polytopic protein structure, and the solid-state NMR spectra for membrane-embedded bR matched most favorably with the recent 1FBB electron crystallography structure. These results suggest that this approach has the potential to yield structural and orientational constraints for large integral polytopic proteins whilst intercalated and functionally competent in a natural membrane.

Membrane protein structure determination using solid-state NMR.

Solid-state NMR is emerging as a method for resolving structural information for large biomolecular complexes, such as membrane-embedded proteins. In principle, there is no molecular weight limit to the use of the approach, although the complexity and volume of data is still outside complete assignment and structural determinations for any large (Mr > approx 30,000) complex unless specific methods to reduce the information content to a manageable amount are employed. Such methods include specific residue-type labeling, labeling of putative segments of a protein, or examination of complexes made up of smaller, manageable units, such as oligomeric ion channels. Labeling possibilities are usually limited to recombinant or synthesized proteins, and labeling strategies often follow models from a bioinformatics approach. In all cases, and in common with most membrane studies, sample preparation is vital, and this activity alone can take considerable effort before NMR can be applied--peptide or protein production (synthesis or expression) followed by reconstitution into bilayers and resolution of suitable sample geometry is still technically challenging. As experience is gained in the field, this development time should decrease. Here, the practical aspects of the use of solid-state NMR for membrane protein structural determinations are presented, as well as how the methodology can be applied. Some successes to date are discussed, with an indication of how the area might develop.

Structural diversity of amyloid fibril formed in human calcitonin as revealed by site-directed 13C solid-state NMR spectroscopy.

Fibril formation in human calcitonin (hCT) from aqueous solution at pH 4.1 was examined and compared with those at pH 3.3 and 7.5 corresponding to three different net charges by means of site-directed (13)C solid-state NMR spectroscopy. Notably, the observed (13)C chemical shifts and lineshapes of the (13)C CP/MAS spectra differed substantially among fibrils prepared at different pHs. It was found that antiparallel beta-sheet structures were formed at pH 7.5 and 4.1 in the central core regions. In the C-terminal region, random coils were formed at both pH 7.5 and 4.1, although the random coil region at pH 4.1 was larger than that at pH 7.5. Fibrillation kinetics analyzed by a two-step autocatalytic reaction mechanism showed that the rate constants k(1) and k(2) for nucleation and maturation reactions of the fibril formation, respectively, were separately determined and the values correlated well with the net positive charges of Lys(18) and His(20) rather than the existence of a negative charge of Asp(15). Further, an attempt was made to assess interatomic distances between amide nitrogen and carbonyl carbon of neighboring chains of (13)C, (15)N-labeled hCT and a model pentapeptide by (13)C REDOR measurements by taking into account its dipolar interaction analyzed by the 3 spin system proposed previously. A unique chain packing of the antiparallel beta-sheets was proposed as a dominant fibril structure, although the possibility of a contribution of chain packing consisting of sliding one or two residues perpendicular to the fibril direction cannot be ruled out. In addition, it appears that the phenyl rings of Phe(16) are aligned on the same side of the beta-sheet and make the beta-sheet stable by forming pi-pi interactions between the beta-strands.

Effect of electrostatic interaction on fibril formation of human calcitonin as studied by high resolution solid state 13C NMR.

Fibrillation of a human calcitonin mutant (hCT) at the position of Asp(15) (D15N-hCT) was examined to reveal the effect of the electrostatic interaction of Asp(15) with charged side chains. The secondary structures of fibrils and soluble monomers in the site-specific (13)C-labeled D15N-hCTs were determined using (13)C cross-polarization magic angle spinning and dipolar decoupled magic angle spinning NMR approaches, sensitive to detect (13)C signals from the fibril and the soluble monomer, respectively. The local conformations and structures of D15N-hCT fibrils at pH 7.5 and 3.2 were found to be similar to each other and those of hCT at pH 3.3 and were interpreted as a mixture of antiparallel and parallel beta-sheets, whereas they were different from the hCT fibril at pH 7.5 whose structure is proposed to be antiparallel beta-sheets. Thus the negatively charged Asp(15) in the hCT molecule turned out to play an essential role in determining the structures and orientations of the hCT molecules. Fibrillation kinetics of D15N-hCT was analyzed using a two-step autocatalytic reaction mechanism. The results indicated that the replacement of Asp(15) with Asn(15) did not reduce the rate constants of the fibril formation but rather increased the rate constants at neutral pH.