Assignment of the vibrational modes of the chromophores of iodopsin and bathoiodopsin: low-temperature fourier transform infrared spectroscopy of 13C- and 2H-labeled iodopsins.

To investigate the chromophore structures of iodopsin and its low-temperature photoproducts, we have assigned their vibrational bands in the Fourier transform infrared (FTIR) spectra using iodopsin samples that were reconstituted with a series of (13)C- and deuterium-labeled retinals. The analyses of the vibrational bands in the fingerprint and hydrogen-out-of-plane (HOOP) regions indicated that the structure of the chromophores in the iodopsin system differs near their centers from those in the rhodopsin system. Compared to rhodopsin, the chromophore of the batho intermediate of iodopsin is twisted in the C(12) to C(14) regions but is more planar around C(11) region. The large amount of twisting was reduced by removing the chloride ion from the iodopsin, suggesting that this twisting hinders the relaxation of the torsion near C(11) necessary for the transition to the lumi intermediate and thus results in the thermal reversion of the batho intermediate back to the iodopsin. From the analyses of the C=NH and C=ND stretching bands, we conclude that the displacement of the Schiff base region upon photoisomerization of the chromophore is restricted, as is the case for rhodopsin. These results indicated that iodopsin's chromophore has a unique structure near its center and that this difference is enhanced by the binding of chloride nearby.

Deuterium NMR structure of retinal in the ground state of rhodopsin.

The conformation of retinal bound to the G protein-coupled receptor rhodopsin is intimately linked to its photochemistry, which initiates the visual process. Site-directed deuterium ((2)H) NMR spectroscopy was used to investigate the structure of retinal within the binding pocket of bovine rhodopsin. Aligned recombinant membranes were studied containing rhodopsin that was regenerated with retinal (2)H-labeled at the C(5), C(9), or C(13) methyl groups by total synthesis. Studies were conducted at temperatures below the gel to liquid-crystalline phase transition of the membrane lipid bilayer, where rotational and translational diffusion of rhodopsin is effectively quenched. The experimental tilt series of (2)H NMR spectra were fit to a theoretical line shape analysis [Nevzorov, A. A., Moltke, S., Heyn, M. P., and Brown, M. F. (1999) J. Am. Chem. Soc. 121, 7636-7643] giving the retinylidene bond orientations with respect to the membrane normal in the dark state. Moreover, the relative orientations of pairs of methyl groups were used to calculate effective torsional angles between different planes of unsaturation of the retinal chromophore. Our results are consistent with significant conformational distortion of retinal, and they have important implications for quantum mechanical calculations of its electronic spectral properties. In particular, we find that the beta-ionone ring has a twisted 6-s-cis conformation, whereas the polyene chain is twisted 12-s-trans. The conformational strain of retinal as revealed by solid-state (2)H NMR is significant for explaining the quantum yields and mechanism of its ultrafast photoisomerization in visual pigments. This work provides a consensus view of the retinal conformation in rhodopsin as seen by X-ray diffraction, solid-state NMR spectroscopy, and quantum chemical calculations.

Discrimination between normal and malignant human gastric tissues by Fourier transform infrared spectroscopy.

The aim of this study was to determine whether malignant and normal human gastric tissues can be distinguished by Fourier transform infrared (FTIR) spectroscopy. Compared with normal tissue, malignant tissues showed significant increases in infrared (IR) absorption in 10 bands lying in a region of 925-1660 cm(-1). Using the 10 IR absorption bands as markers, discriminant analysis was carried out for tissue discrimination. As a result, 22 out of the 23 gastric cancer samples and 9 out of the 12 gastric normal samples were correctly segregated, yielding 88.6% accuracy. The present results suggest that FTIR spectroscopy is a useful tool for screening gastric cancer.

Absolute configurational assignments of secondary amines by CD-sensitive dimeric zinc porphyrin host.

A general chiroptical protocol for determination of absolute configuration of secondary amines including acyclic and cyclic aliphatic amines, aromatic amines, amino acids, and amino alcohols is described. The chiral substrate is linked to the achiral carrier moiety (3-N-Boc-amino-propyl-N-Boc-amino)acetic acid 1 (BocHNCH(2)CH(2)CH(2)BocNCH(2)COOH), which after deprotection, yields a bidentate conjugate, capable of forming a 1:1 host/guest complex with dimeric zinc porphyrin host 2. As in the cases of primary amines and secondary alcohols reported earlier, the complexation of secondary amine conjugates to porphyrin tweezer host 2 represents a stereodifferentiating process, where the large (L) group at the stereogenic center (assigned on the basis of conformational energies A value) protrudes from the porphyrin binding pocket. This leads to formation of host/guest complexes with a preferred porphyrin helicity that exhibit intense exciton split CD spectra. It was found that the chiral sense of porphyrin twist is clearly controlled by the stereogenic center despite the Z/E conformational complexity around the tertiary amide bond of secondary amine conjugates that has greatly hampered previous configurational assignments. Thus, in cases where there is no ambiguity regarding the relative steric size of substituents, the observed CD couplet can be applied for straightforward assignment of absolute configurations. In addition, to extend the application to more difficult cases a molecular mechanics calculation approach using the Merck Molecular Force Field (MMFFs) was developed; this provides conformational information of host/guest complexes and leads to prediction of preferred porphyrin helicity independent of conformational A values. This chiroptical protocol in combination with molecular modeling represents a general method for configurational assignments of secondary amines.