Theory of Cross-Polarization Scattering at the Upper Hybrid Resonance

A study is made of the cross-polarization scattering by magnetic field fluctuations and the resulting conversion of an extraordinary wave into an ordinary wave in the vicinity of the upper hybrid resonance. It is shown that the scattering efficiency increases with decreasing fluctuation wavelength. It is also demonstrated that the accompanying spurious signal from the cross-polarization scattering by density fluctuations is suppressed.     

New approach to study fast and slow motions in lipid bilayers: application to dimyristoylphosphatidylcholine-cholesterol interactions.

Natural abundance 13C solid-state nuclear magnetic resonance spectroscopy was used to investigate the effect of the incorporation of cholesterol on the dynamics of dimyristoylphosphatidylcholine (DMPC) bilayers in the liquid-crystalline phase. In particular, the use of a combination of the cross-polarization and magic angle spinning techniques allows one to obtain very high resolution spectra from which can be distinguished several resonances attributed to the polar head group, the glycerol backbone, and the acyl chains of the lipid molecule. To examine both the fast and slow motions of the lipid bilayers, 1H spin-lattice relaxation times as well as proton and carbon spin-lattice relaxation times in the rotating frame were measured for each resolved resonance of DMPC. The use of the newly developed ramped-amplitude cross-polarization technique results in a significant increase in the stability of the cross-polarization conditions, especially for molecular groups undergoing rapid motions. The combination of T1 and T1 rho measurements indicates that the presence of cholesterol significantly decreases the rate and/or amplitude of both the high and low frequency motions in the DMPC bilayers. This effect is particularly important for the lipid acyl chains and the glycerol backbone region.     

Band-selective hetero- and homonuclear cross-polarization using trains of shaped pulses

Summary The performance of solution cross-polarization using trains of shaped pulses on two channels is investigated by computer simulation and experiment. It is determined that a Waltz modulation pattern of Gaussian pulses of individual flip angles of 225°, issued to two coupled spins simulatneously, yields excellent coherence transfer with good phasing behavior. Simulations and experimental verification were carried out for both heteronuclear cross-polarization between two restricted areas (e.g. ¹H–¹³C) and for homonuclear cross-polarization between two spectral regions (e.g. ¹³CO–¹³C). It is shown that shaped cross-polarization behaves as pure heteronuclear cross-polarization when the two radiofrequency (rf) fields are far apart, while it behaves in some aspects analogous to homonuclear cross-polarization when the two rf fields approach each other. The novel coherence-transfer sequence, referred to as cosine-modulated shaped Waltz (CSW), was implemented in a 3D (H)C(CCO)NH experiment using an 18-kDa isotopically labeled protein.     

A study of a Calpha,beta-didehydroalanine homo-oligopeptide series in the solid-state by 13C cross-polarization magic angle spinning NMR.

The fully extended peptide conformation (2.0(5)-helix) has been investigated for the first time in the solid-state by 13C cross-polarization magic angle spinning NMR. The compounds examined are members of a terminally protected, homo-oligopeptide series (from monomer through hexamer) based on Calpha,beta-didehydroalanine.     

Efficient Broadband Transmissive 90° Polarization Rotation Using a Single Layer of L-shaped Particles Inside a Glass Cube

We realize 90° polarization rotation with both high polarization conversion efficiency and broad bandwidth by using a single layer of L-shaped particles inside a glass cube. The simulation results show that Fabry-Perot resonance effect enhances the transmission for both co-polarization and cross-polarization light in the L-shaped layer. And the co-polarization electric field component has been suppressed in the far field because of the destructive interference. The simulation results also show that the spectral band of peak polarization rotation can be shifted by changing the size parameters. This broadband polarization rotation mechanism may be very useful in designing polarization rotators.     

Phase transitions of phosphatidylcholine bilayers as revealed by cross-polarization efficiency of 31P-NMR

Cross-polarization efficiency is found to be an excellent NMR parameter to reflect dynamic properties of phospholipid bilayers. This parameter is quite sensitive to the pretransition rather than the main transition, in contrast to other NMR parameters studied so far. An investigation of the cross-polarization efficiency provides us with information on the relatively slower motions of the phospholipid molecules.     

Metalens Focusing the Co-/cross-polarized Lights in Longitudinal Direction

Recently, metasurface has attracted lots of attentions because of its great capability in phase engineering for the transmitted cross-polarization light, and many functional optical elements have been designed and investigated. Commonly, the co-polarization and cross-polarization lights will coexist in the transmitted fields. Here, we propose a planar metalens composed of L-shaped nanoholes, which can focus an incident plane wave to two different focal spots in longitudinal direction for the co-polarized and cross-polarized transmitted lights respectively. In our design, the focal length of the transmitted cross-polarized lights can be tuned easily according to Fermat principle. Meanwhile, the focal length of the co-polarized transmitted lights can also be modulated by the ring number of the designed metalens. Because of the polarization-independent characteristic of the L-shaped nanoantenna, the designed planar metalens can also be suitable for both linear and circular polarized incident lights.     

The influence of hydration on the conformation of bovine serum albumin studied by solid-state 13C-nmr spectroscopy

¹³C proton-decoupled cross-polarization magic-angle spinning nmr spectra of bovine serum albumin are reported as a function of hydration. Increases in hydration level enhance the resolution of the peak centered at about 40 ppm but has little or no effect on the other spectral peaks. Hydration has little effect on either the rotating frame proton spin–lattice relaxation time or the cross-relaxation time for any of the peaks, suggesting that the efficiency of dipolar coupling is largely preserved on hydration of the protein. Resolution enhancement of the peak at 40 ppm is not understood, but possible sources of the behavior include a decrease in the line width of contributing resonances from lysine ε carbons due to increased motional averaging on hydration, reordering of disulfide bridges, and titration shifts induced by hydration. Hydration of bovine serum albumin appears to have little effect on the distribution of conformations sampled by the protein so that the broad distribution of conformations observed in the dry state is also observed in the fully hydrated state. This is in contrast to lysozyme where significant ordering of the conformation is seen on hydration. © 1993 John Wiley & Sons, Inc.     

Biological membranes are rich in low-frequency motion

Using ¹³C cross-polarization NMR techniques, we have found that the effect of protein on the dynamics of the hydrocarbon interior of a series of biological membranes is to depress the intensity of motion on the nanosecond timescale (i.e., $\text{T}{}_1$ becomes longer) and to enhance the intensity of motion on the timescale of tens of microseconds (i.e., $\text{T}{}_{\mathrm{<mtext>1</mtext><mtext>p</mtext>}}$ becomes shorter).     

The effect of water content on the ordered/disordered structures in starches

(13)C cross-polarization magic angle spinning NMR has been used to study the ordered and disordered structures of starches with different water contents. The amorphous regions of starch have been shown to produce NMR patterns only if they are in a glassy state, the widths, positions, and areas of the peaks to some extent being dependent on the temperature and the water content of the starch. In the amorphous region, the peaks were all Gaussian in shape, while the peaks in the ordered regions had Lorentz profiles. Water contents in the range 10-50% did not influence the proportion of double helices in the starch. Decreasing the water content to 1-3%, however, resulted in a significant decrease in the proportion of double helices, the effect being greater in B- than in A-type starches. It is suggested that short-range order structures in starches (double helices) are stabilized by becoming part of long-range order structures (crystallites).     

Laser light-scattering studies of bull spermatozoa. I. Orientational effects.

Calculations based on the known dimensions of bull spermatozoa show that the scattered light intensity is strongly dependent upon the relative orientation of the particle to the incident beam. The magnitude of this effect of apparently much greater than for other systems where motility has been investigated by dynamic light scattering. The calculations show that the scattering source can be approximated by a small spinning mirror, and consequently the greatest light intensity at the detector results from cells swimming in a direction perpendicular to the scattering vector. The calculations are in substantial agreement with photographic observations, as well as direct measurements of the scattered intensity. Previous treatments of dynamic light scattering from swimming bull spermatozoa based on point scattering models are shown to be incorrect.     

Elucidation of intermediate (mobile) and slow (solidlike) protein motions in bovine lens homogenates by carbon-13 NMR spectroscopy

The motional dynamics of lens cytoplasmic proteins present in calf lens homogenates were investigated by two 13C nuclear magnetic resonance (NMR) techniques sensitive to molecular motion to further define the organizational differences between the cortex and nucleus. For the study of intermediate (mobile) protein rotational reorientation motion time scales [rotational correlation time (tau 0) range of 1-500 ns], we employed 13C off-resonance rotating frame spin-lattice relaxation, whereas for the study of slow (solidlike) motions (tau 0 greater than or equal to 10 microseconds) we used the solid-state NMR techniques of dipolar decoupling and cross-polarization. The frequency dependence of the peptide bond carbonyl off-resonance rotating frame spectral intensity ratio of the lens proteins present in native calf nuclear homogenate (42% protein) at 35 degrees C indicates the presence of a polydisperse mobile protein fraction with a tau 0,eff (mean) value of 57 ns. This mean value is consistent with the average value calculated from the known water-soluble nuclear lens protein polydispersity assuming a cytoplasmic viscosity 3 times that of pure water. Lowering the temperature to 1 degree C, a temperature which produces the cold cataract, results in an overall decrease in tau 0,eff to 43 ns, suggesting a selective removal of beta H-, LM-, and possibly gamma s-crystallins from the mobile lens protein population. The presence of solidlike or motionally restricted protein species was established by dipolar decoupling and cross-polarization. The fraction of motionally restricted protein in the nuclear region varied from 0.35 to 0.45 in the temperature range of 35-1 degree C. For native cortical homogenate (25% protein), the off-resonances rotating frame spectral intensity ratio frequency-dependent curves for the protein carbonyl resonance yielded tau 0,eff values of 34 and 80 ns at 35 and 1 degree C, respectively. Both values were reconciled with the known lens cortex soluble protein polydispersity using an assumed cytoplasmic viscosity 1.5 times that of pure water at the same temperature. Comparison of proton dipolar-decoupled and nondecoupled 13C NMR spectra of native cortical homogenate at 20 degrees C indicates the absence of significant contributions from slowly tumbling, motionally restricted species. This interpretation was confirmed by the failure to detect significant lens protein 13C-1H cross-polarization at this temperature. However, at 1 degree C, the fraction of solidlike protein was 0.15. Concentrated cortical homogenates at 20 degrees C (42% protein), by contrast, gave cross-polarization spectra with maximum absolute signal intensities 50-70% of native nuclear homogenates, but with similar magnetization parameters...     

High-resolution solid-state nuclear magnetic resonance spectra of dentin collagen

Insoluble collagen of bovine dentin was characterized by high-resolution solid-state 13C nuclear magnetic resonance (NMR) spectroscopy using a cross-polarization magic angle spinning procedure. A downfield shift was observed in the signal of hydroxyproline C beta compared with that in skin collagen, indicating a distortion in the hydroxyproline structure. A signal of 31P NMR was detected in dentin collagen that was compatible with the presence of matrix-associated phosphoprotein.     

Role of Stopband and Localized Surface Plasmon Resonance in Raman Scattering from Metallo-Dielectric Photonic Crystals

Self-assembled photonic crystals grown from different colloidal sizes are coated with gold nanoparticles preferentially on their surface. The effect of localized surface plasmon resonance and the photonic stopband on the Raman scattering from these crystals is analyzed from the angle-dependent scattering measurements. The coupling of photonic and plasmonic modes at the surface of the photonic crystal is verified by measuring the increment in Raman scattering from the crystals containing the gold nanoparticles, and this increment is found to follow the spectral trend of localized surface plasmon resonance.     

Magic-angle N-15 NMR study of nitrate metabolism of Neurospora crassa

Magic-angle cross-polarization ¹⁵N nmr spectra of intact lyophilized mycelia from $\text{N.}\text{crassa}$ cultured on media containing [¹⁵N] nitrate have been obtained at 9.12 MHz. The time development of the uptake and distribution of label into protein and amino-acid metabolites can be observed directly. Nitrate metabolism is delayed about one hour if the cells innoculating the culture are grown on nitrate-free medium.     

Secondary structures of peptides: 5 · 15N n.m.r. CP/MAS spectroscopy of solid polypeptides and gramicidin-S

30.5 MHz ¹⁵N m.m.r. (CP/MAS) spectra of various solid polypeptides were measured using the cross-polarization/magic angle spinning technique. In order to obtain optimum signal-to-noise ratios, relatively short contact times (1 ± 0.5 ms) are required, because the cross-polarization times (T_NH) are short and because the proton rotating-frame relaxation times (T_1p) are in the order of 20 ms. The ¹⁵N n.m.r. signals of copolypeptides may be sensitive to sequence effects; yet they are in most cases more sensitive to the nature of the secondary structure. The signals of α-helices absorb ca. 8–10 ppm upfield of β-sheet structures, whereas the polyglycine II helix absorbs downfield. The natural abundance spectrum of crystalline gramicidin-S exhibits a signal at ?247 ppm, a characteristic chemical shift of the antiparallel pleated sheet structure.     

Involvement of an SHP-2-Rho small G protein pathway in hepatocyte growth factor/scatter factor-induced cell scattering

Hepatocyte growth factor/scatter factor (HGF/SF) induces cell scattering through the tyrosine kinase-type HGF/SF receptor c-Met. We have previously shown that Rho small G protein (Rho) is involved in the HGF/SF-induced scattering of Madin-Darby canine kidney (MDCK) cells by regulating at least the assembly and disassembly of stress fibers and focal adhesions, but it remains unknown how c-Met regulates Rho activity. We have found here a novel signaling pathway of c-Met consisting of SHP-2-Rho that regulates the assembly and disassembly of stress fibers and focal adhesions in MDCK cells. SHP-2 is a protein-tyrosine phosphatase that contains src homology-2 domains. Expression of a dominant negative mutant of SHP-2 (SHP-2-C/S) markedly increased the formation of stress fibers and focal adhesions in MDCK cells and inhibited their scattering. C3, a Clostridium botulinum ADP-ribosyltransferase, and Y-27632, a specific inhibitor for ROCK, reversed the stimulatory effect of SHP-2-C/S on stress fiber formation and the inhibitory effect on cell scattering. Vav2 is a GDP/GTP exchange protein for Rho. Expression of a dominant negative mutant of Vav2 blocked the stimulatory effect of SHP-2-C/S on stress fiber formation. Conversely, expression of mutants of Vav2 that increased stress fiber formation inhibited HGF/SF-induced cell scattering. These results indicate that SHP-2 physiologically modulates the activity of Rho to form stress fibers and focal adhesions and thereby regulates HGF/SF-induced cell scattering. In addition, Vav2 may be involved in the SHP-2-Rho pathway.     

Solubilization mechanism and characterization of the structural change of bacterial cellulose in regenerated states through ionic liquid treatment

A statistical approach was used to characterize the heterogeneous structures of bacterial cellulose samples pretreated with four kinds of ionic liquids (ILs). The structural heterogeneity of these samples was measured by Fourier transform infrared spectroscopy as well as solid-state NMR methods such as cross-polarization magic-angle spinning and dipolar-assisted rotational resonance. The obtained data matrices were then evaluated by principal components analysis. The measured 1-D data clearly revealed the modification of crystalline cellulose; in addition, the statistical approach revealed subtle structural changes that occurred upon pretreatment with different kinds of ILs. To investigate whether such regenerated structural changes occurred because of solubilization, we examined the intermolecular nuclear Overhauser effect between cellulose and an IL. Our results clarify how the nucleophilic imidazole is attacked and suggest that the cation of the IL is associated with the collapse of hydrogen bonds in cellulose.     

Light Scattering at Various Angles: Theoretical Predictions of the Effects of Particle Volume Changes

The Mie theory of scattering is used to provide new information on how changes in particle volume, with no change in dry weight, should influence light scattering for various scattering angles and particle sizes. Many biological cells (e.g., algal cells, erythrocytes) and large subcellular structures (e.g., chloroplasts, mitochondria) in suspension undergo this type of reversible volume change, a change which is related to changes in the rates of cellular processes. A previous study examined the effects of such volume changes on total scattering. In this paper scattering at 10° is found to follow total scattering closely, but scattering at 45°, 90°, 135°, and 170° behaves differently. Small volume changes can cause very large observable changes in large angle scattering if the sample particles are uniform in size; however, the natural particle size heterogeneity of most samples would mask this effect. For heterogeneous samples of most particle size ranges, particle shrink-age is found to increase large angle scattering.     

A selective resonance scattering assay for immunoglobulin G using Cu(II)-ascorbic acid-immunonanogold reaction

In sodium acetate–acetic acid buffer solution, Au, Ag, Pt, Pd, Fe₃O₄, and Cu₂O nanoparticles have catalytic enhancement effect on the reduction of Cu²⁺ by ascorbic acid to form large copper particles that exhibit a strong resonance scattering peak at 610 nm. Those nanocatalytic reactions were studied by the resonance scattering spectral technique, and smaller nanogold exhibited stronger catalytic enhancement effect in pH 4.2 sodium acetate–acetic acid buffer solution. The resonance scattering intensity at 610 nm increased linearly with the concentrations of 0.02 to 1.60, 0.040 to 1.20, and 0.12 to 4.70 nM nanogold in sizes of 5, 10, and 15 nm with detection limits of 0.010, 0.030, and 0.10 nM, respectively. An immunonanogold-catalytic resonance scattering bioassay was established, combining the immunonanogold-catalytic effect on CuSO₄–ascorbic acid reaction with the resonance scattering detection technique. As a model, 0.03 to 7.5 ng ml⁻¹ immunoglobulin G can be assayed by this immunonanogold-catalytic resonance scattering bioassay with a detection limit of 0.015 ng ml⁻¹.