Empirical calculations of dinucleotide optical activity

In this paper we present calculations of dinucleotide optical activity based on the exciton-coupled oscillator and generalized susceptibility theories of CD. Our application of these methods utilizes experimental transition moment data for the nucleic acids and does not require explicit wavefunctions for the monomers. In addition to near-uv π-π* states, the calculations include n-π* and far-uv π-π* transitions recently characterized by Clark. We also show that correlated motions of electrons in the ground state of a system is reflected in the net CD summed over all transitions. Sample calculations for dinucleotides in several conformations illustrate the methods.     

Optical and conformational properties of the 7-(beta-D-ribofuranosyl) purines

The optical and conformational properties of certain 7-ribosyl purines have been studied using several experimental and theoretical methods. The CD, MCD, and absorption spectra of the 7-ribosyl purines and their cations have been determined experimentally with some solvent effects being noted. Theoretically we have used the SCF-CI and CNDO molecular orbital calculations to determine the optical properties of the bases; Simpson's bond exciton theory to determine the optical properties of the bases; Simpson's bond exciton theory to determine the optical properties of the ribose moiety; the optical activity was determined by the dipole coupling and electricmagnetic coupling equations; and the conformational energy calculations are included as a basis for excluding highly improbable conformations. On the basis of these calculations, we concluded that the oxy derivatives and the amino derivatives are predominately in the “extreme anti” conformation and “standard anti” conformation, respectively. However, the conclusions are tentative since at the present time the band assignments are not unequivocal. At least one n-π* transition has been identified in the spectra which is not notably sensitive to pH and solvent effects. Several implications of this observation are discussed.     

Circular dichroism of the alkyl amino acids in the vacuum ultraviolet

The circular dichroism and absorption for five alkyl amino acids as zwitterions has now been measured to 160 nm. Two bands are found, the nπ* at long wavelengths and ππ* at short wavelengths. In an effort to extract conformal information from the circular dichroism measurmenths, the circular dichroism spectra for these molecules is calculated using an independent systems apporach. It is found that the signs calculated using these methods are quite reliable, but that reliable magnitudes must await more accurate data to use in the calculations. Comparing the signs for both the measured and calculated circular dichriosm it if possible to determine the region inhabited by the carboxylate anion chromophore of these amino acid zwitterions. The greatest failure of the calculations is that thay are unable to explain the sigmoidal shape of the nπ* transition in proline. The problems facing workers trying to make calculations to relate circular dichroism measurements to conformation are discussed.     

Optical activity of single-stranded polydeoxyadenylic and polyriboadenylic acids; dependence of adenine chromophore cotton effects on polymer conformation

Circular dichroism (CD) curves are reported for poly dA, (pdA)₆, (pdA)₂, poly A, ApAp, ApA, AMP, dApA, pdApA, A-2′-O-methyl pA, and A-2′-O-methyl pAp. Analysis of these curves indicated the presence of single CD bands at 228–230 mμ and at 278–280 mμ in oligomers longer than dinucleotides. In the case of dinucleotides and mononucleotides (from the literature, in addition to those studied here), the 230 mμ CD of band appears but the 280 mμ CD band does not. We assign the 230 mμ band to a very weak π–π* transition at this wavelength. From theoretical considerations, we show that the 280 mμ band is not an exciton component of the strong π–π* transition at 260 mμ in adenine. We conclude that the 280 mμ CD band must be assigned to a distinct absorption, not previously reported, which we suggest arises from an n–π* transition. The fact that the n–π* CD band at 280 mμ is not seen in mononucleotides or dinucleotides is ascribed to solvation of the adenine ring by water, which shifts the band to shorter wavelengths. Therefore, only interior residues of oligomers have the 280 mμ band, and the optical activity of a polymer cannot be computed from that of a dinucleotide, by using a nearest-neighbor approximation. The existence of this end effect hag been tested, by taking it into account in computing the rotational strengths of the 278 mμ n–π* transition for several oligomers; it is pointed out that a more sensitive test of this end effect would require CD data for the oligo dA series of 3 to 5 residues. We speculate about the structural and optical differences between poly dA and poly A, and point out the need for a theoretical treatment of n–π* Cotton effects in polynucleotides.     

Theoretical π-π* absorption and circular dichroic spectra of helical poly(L-proline) forms I and II

Absorption and CD spectra of the π-π* transition near 200 nm are calculated for helical (Pro)_n I and II (n = 6, 10) using the dipole interaction model, including interactions among all atoms, with optical parameters obtained from previous studies of related molecules. Calculated spectra for (Ala)_n and (Pro)_n in the same conformation show marked differences. The spectra for (Pro)_n are sensitive to side-chain structure but are found to agree reasonably well with exeriment for forms I and II when the side-chain C? C bond length is set at 1.54 Å, with structural data otherwise obtained from x-ray diffraction studies.     

Optical activity of simple cyclic amides in solution

The cyclic dipeptide, L -alanylglycyl anhydride, has been studied by optical rotatory dispersion; both L -alanylglycyl anhydride and the lactam, L -3-aminopyrrolidin-2-one, have been studied by circular dichroism. In hydroxylic solvents the circular dichroism spectra of 3-aminopyrrolidin-2-one can be attributed to an n–π* transition near 220 mμ and a π–π* transition near 190 mμ. In these solvents the optical activity of L -alanylglycyl anhydride can be explained as being due to contributions of n–π* transitions and a split π–π* transition. In acetonitrile, however, the circular dichroism spectrum of 3-aminopyrrolidin-2-one shows an additional apparent minimum near 200 mμ. The CD spectrum of the dipeptide is also quite distinctive in this solvent. The possible nature of the band at 200 mμ and the implications of these findings are discussed.     

Study by circular dichroism and optical rotatory dispersion of polypeptides with aromatic side-chain chromophores

Poly(ortho-, meta-, and para-γ-nitrobenzyl-L -glutamates) were studied by circular dichroism (CD) and optical rotatory dispersion (ORD) in two helicogenic solvents, hexafluoroisopropanol (HFIP) and dichloroethane (EDC), and two non-helicogenic solvents, dichloracetic acid (DCA) and trifluoroacetic acid (TFA). The corresponding glutamates were also studied in DCA and TFA. The symmetric nitrobenzylic chromophore is optically active when the polymers are in solution in DCA and TFA. The corresponding glutamates are also optically active under the same conditions. Thus, it was not possible to explain the origin of the optical activity of the side-chain chromophore when the polymer is in solution in a helicogenic solvent. Nevertheless, from a side-chain dichroic band, a helix–coil transition curve was determined and the stability of each poly(γ-nitrobenzyl-L -glutamate) given; this stability depends on the position of the nitro substituent on the aromatic ring.     

The circular dichroism of aromatic polypeptides: Theoretical studies of poly-L-phenylalanine and some para-substituted derivatives

We have calculated rotational strengths and circular dichroism (CD) curves for sidechain and backbone transitions in poly-L -Phenylalanine (PLP), POLY-p-amino-L -phenylalanine (PPALP), poly-p-chloro-L -phenylalanine (PPCLP), poly-o-acetyl-L -tyrosine (POALT), and poly-p-nitro-L -phenylanine (PPNLP), using methods applied previously to poly-L -tyrosine (PLT). Comparison of the theoretical CD curves with available experimental data for PLP and PPALP indicate that these polypeptides form right-handed helices with side-chain conformations similar to that of PLT. For PPNLP, where experimental data are also available, no conformational assignment could be made, as none of the calculated curves gave good agreement with experiment. Possible reasons for this lack of agreement are discussed. For the other two polypeptides, PPCLP and POALT, although no experimental data are yet available, the calculated curves indicate that an unambiguous assignment should be possible. For the conformations (RA and LA) in which the side chains are packed more loosely, there are strong similarities in the calculated CD curves of a particular conformation, regardless of the para substituent. In the tighter R1 and L1 conformations, few generalizations can be drawn, each derivative having a distinctive pattern. In PLP, PPCLP, and POALT, where the side-chain L^a band is in the 200–210 nm region, the L1 conformation exhibits a negative nπ* rotational strength, opposite to that expected for a left-handed helix. One must therefore be cautious about assigning the helix sense of aromatic polypeptides on the basis of the sign of the nπ* CD band. Side-chain nπ* transitions present in POALT and PPNLP were found to have small rotational strength.     

Circular dichroism of nucleic acid monomers. II. Derivation and application to polymers of a consistent set of guanine and cytosine transition parameters

An approximate semiempirical procedure has been developed in order to derive nucleic acid monomer π → π* electronic transition moment parameters. Using the approximate procedure, guanine (G) and cytosine (C) transition moment parameters have been derived from agreement found between calculated weight-averaged and measured CD spectra of cyclic-GMP and cyclic-CMP. The derived base transition moment parameters have been assessed in CD spectral calculations on some G- and C-containing nucleic acids for which reasonably good structural information exists. An attempt was also made at evaluating the likely CD spectral contributions of G and C electric n → π* transition moments whose magnitudes were taken to be the maximum expected. Overall, the results indicate that the derived G and C π → π* transition moment parameters are more successful in nucleic acid CD spectral calculations than those used in previous DeVoe theory CD calculations. In addition, the results indicate that electric n → π* transitions may be of importance in understanding nucleic acid monomer CD spectra but appear to be relatively unimportant in understanding nucleic acid polymer CD spectra. It is concluded that the derived G and C π → π* parameters are more useful in DeVoe theory CD calculations than parameters used previously.     

Signatures of n→π* interactions in proteins

The folding of proteins is directed by a variety of interactions, including hydrogen bonding, electrostatics, van der Waals' interactions, and the hydrophobic effect. We have argued previously that an n→π* interaction between carbonyl groups be added to this list. In an n→π* interaction, the lone pair (n) of one carbonyl oxygen overlaps with the π* antibonding orbital of another carbonyl group. The tendency of backbone carbonyl groups in proteins to engage in this interaction has consequences for the structures of folded proteins that we unveil herein. First, we employ density functional theory to demonstrate that the n→π* interaction causes the carbonyl carbon to deviate from planarity. Then, we detect this signature of the n→π* interaction in high‐resolution structures of proteins. Finally, we demonstrate through natural population analysis that the n→π* interaction causes polarization of the electron density in carbonyl groups and detect that polarization in the electron density map of cholesterol oxidase, further validating the existence of n→π* interactions. We conclude that the n→π* interaction is operative in folded proteins.     

Random copolymers of alpha-benzyl-L-aspartate with ortho- and para-nitrobenzyl-L-aspartates. Intrinsic and extrinsic dichroic bands and the left-to-right-handed alpha-helical transition.

Copolymers of benzylaspartate with the corresponding para-nitro and ortho-nitro derivatives are known to undergo, at increasing nitro content, a transition from a left-handed α-helical conformation to a right-handed α-helical conformation. The circular dichroism associated with the n, π* transition of the amide group, as well as the extrinsic bands associated with the nitrobenzyl chromophore, have been studied for these copolymers as a function of the nitro content. The circular dichroism associated with the 330-nm extrinsic band is shown to present an abrupt change, which parallels the change in the 222-nm band characteristic of the left- to right-handed helix transition. The intensity of the 222-nm CD band seems unaffected by the interaction with the side-band chromophore. The circular dichroism associated with the 330-nm band is much stronger in the right-handed conformation and is unaffected by increasing interactions between side chains. Interpretation in the light of the possible mechanism for optical activity of helical molecules seems to indicate that the 330-nm extrinsic effect is essentially due to the Condon, Altar, and Eyring (CAE) mechanism and μ-m perturbation (in Schellmann terminology) on the side-chain chromophore n, π* transition.     

In-silico analysis of substituent effect on the static first order hyperpolarizability of electron donating mono substituted Chalcone derivatives

Noncentrosymmetric π conjugated systems with suitable electron donor acceptor groups play a crucial role in material NLO activity. The influence of an electron donating mono substituent at the para position of the phenylene ring of chalcone was investigated as a resource for second harmonic generation. The geometrical optimization of 11 electron donating group substituted chalcones were performed using density functional theory at the B3LYP/6-311G(d,p) level and compared with experimental geometrical parameters of five reported chalcones. All the derivatives are transparent to visible radiation as shown by the electronic absorption spectra investigated by the TDDFT-CAM B3LYP/6-311G(d,p) method, and the maximum absorption wavelength was due to the π_PhB?→?π* transition. The first order hyperpolarizability β_tot, calculated using the CAM B3LYP/6-311G(d,p) method, increases with the electron donating ability of the substituent, and the largest β_tot was observed for dimethylamino substituent. The Hammett substituent constant (σ_p) shows good linear correlation with β, λ_max, and E_gap in the ground state. The Brown constant (σ_p⁺) was better correlated indicating the polarization of carbonyl group in the excited state. Frontier molecular orbitals also reveal the valence electron excitation. Correlation of σ_p with various parameters was analyzed to assess the property interrelationship with electronic reorganization in the molecule. The electronic structures of molecular fragments were described in terms of natural bond orbital analysis, which shows intramolecular interactions.     

Interactions between purine derivatives: Electronic spectral studies. I. Electronic transitions in caffeine monomer and exciton coupling in caffeine dimer

The concentration dependence of the ultraviolet absorption spectrum of aqueous solutions of caffeine has been studied. Individual species spectra have been derived for the monomer, dimer, and tetramer of caffeine. The emission spectrum of caffeine in aqueous solution and the dichroic spectra in oriented poly(vinyl alcohol) and polyethylene films have been measured. The long-wavelength tail of the absorption spectrum of caffeine in non-polar environment has been found to incorporate at least one carbonyl(π*, n) transition. Dichroic spectral data and molecular orbital calculations have been used to assign transition moment directions to the (π*,π) transitions. The lowest energy (π*,π) transition, responsible for the near-ultraviolet absorption peak in aqueous solution of caffeine, has been used for the study of degenerate exciton interactions in the dimeric species of caffeine. Assuming that the caffeine molecules in the dimer are stacked in parallel planes, theoretical calculations of the ground-state interactions and of the degenerate exciton interactions have been combined with experimental data and a unique model for the dimer of caffeine has been derived. The transfer rate of energy between the molecules in the dimer is of the order of 10¹³_S^?1.     

Synthesis of 5‐tert‐butyl‐1‐(3‐tert‐butyldimethylsiloxy)phenyl‐4,4‐dimethyl‐2,6,7‐trioxabicyclo[3.2.0]heptanes and their fluoride‐induced chemiluminescent decomposition: effect of a phenolic electron donor on the CIEEL decay rate in aprotic polar solvent

Four bicyclic dioxetanes bearing a phenolic substituent, 3‐tert‐butyldimethylsiloxy‐4‐chlorophenyl ( 3a ), 5‐tert‐butyldimethylsiloxy‐4‐chloro‐2‐ethylphenyl ( 3b ), 5‐tert‐butyldimethylsiloxy‐2‐ethylphenyl ( 3c ), and 3‐tert‐butyldimethylsiloxy‐4‐ethylphenyl ( 3d ), were synthesized. All dioxetanes 3a – 3d gave intense blue light on treatment with tetrabutylammonium fluoride (TBAF) in DMSO or acetonitrile. Kinetic study on the fluoride‐induced CIEEL decay of these dioxetanes 3a – 3d and the parent dioxetane 2b revealed that the para‐substitution with chlorine on the phenolic moiety of dioxetane increases free energy of activation (ΔG?), while the para‐substitution with ethyl on the aryl decreases ΔG?. On the other hand, substitution with an ethyl at the ortho‐position instead of the para‐position was found to increase ΔG? and to suppress the CIEEL decay. This fact is attributed to the steric factor of the ortho‐ethyl group which would prevent the aromatic ring from rotating freely around the axis joined to the peroxide ring, and supports the suggestion for a CIEEL‐active dioxetane bearing a phenolic moiety that an intramolecular electron transfer occurs preferentially from the phenolic donor to O–O of the dioxetane ring, when the aromatic ring lies in a certain conformation(s). Copyright © 2002 John Wiley & Sons, Ltd.     

Optical properties and viscosity of hyaluronic acid in mixed solvents: Evidence of conformational transition

Circular dichroism, optical rotatory dispersion, and viscosity of hyaluronic acid at various solvents compositions, concentrations, and pH values have been studied. The data show a large change in the molecular properties in organic/water solvents such as ethanol, p-dioxane, or acetonitrile/water at pH ? pK_a. At this pH range of aqueous solution, hyaluronic acid shows a CD minimum near 210 nm whereas in the presence of organic solvent it exhibits a strong negative dichroism (below 200 nm) and a positive band near 226 nm. It undergoes a sharp, cooperative transition with respect to pH and solvent. The observed CD features are assigned to the π-π* and n-π* transitions of the amide and carboxyl chromophores. The ORD results show a gradual blue shift of trough at 220 nm with increasing magnitude of rotation when the organic solvents and hydrogen ion concentrations are increased. A one-term Drude's equation was used to analyze the ORD data, and the result show a variation of dispersion parameters with different solvents in accordance with the observed CD changes. The intrinsic viscosity of hyaluronic acid in mixed solvent at pH 2.6 is lower than that of aqueous solution. All the observed property changes of hyaluronic acid are reversed on addition of foramide in mixed solvents indicating that the hydrogen bonds are involved in this transition. The observed spectroscopic and hydrodynamic features are attributed to a conformational change of hyaluronic acid in a mixed solvent involving intramolecular hydrogen bonding between the acetamido and carboxyl groups. The possible conformational state of hyaluronic acid in solution under various conditions is discussed in terms of the reported helical structure of hyaluronic acid from x-ray diffraction studies.     

The optical properties of alanine and proline diketopiperazines

The optical properties of the diketopiperazine chromophore of the cyclic dipeptides have been investigated as a function of molecular conformation. The rotatory strengths of L -alanyl–L -alanine diketopiperazine and L -prolyl–L -proline diketopiperazine have been calculated as a function of the angle of fold of the diketopiperazine ring. The results of these theoretical calculations have been compared with experimental circular dichroism and optical rotatory dispersion data. It is shown that the observed optical properties of these molecules can be explained only if their diketopiperazine rings are folded in opposite directions. The direction of fold is established for each molecule. In solution, the diketopiperazine ring of L -alanyl-L -alanine diketopiperazine is folded in the direction opposite to that found by X-ray diffraction analysis of crystals. It has been observed that the degree of conservatism of the π → π* couplet of L -propyl–L -proline diketopiperazine depends markedly upon the nature of the solvent that is used. In addition, a shoulder has been discovered in the CD spectrum of L -alanyl–L -alanine diketopiperazine, which may not be directly attributable to the n → π* and π → π* transitions of the peptide chromophores.     

Substituent — Directed Aralkylation and Alkylation Reactions of the Tricyclic Analogues of Acyclovir and Guanosine

Abstract

Aryl or tert-butyl substituent in the 6 position of 3,9-dihydro-3-[(2-hydroxyethoxy)methyl]-9-oxo-6-R-5H-imidazo[1,2-α]purine (6-R-TACV)¹ 1 partly directs aralkylation reactions into unusual positions: N-4 to give 3 and C-7 to give N-5, 7-disubstituted or N-4, 7-disubstituted derivatives. In the case of alkylation the effect is limited to aryl substituent and position N-4. Replacement of acyclic moiety of 1 with a ribosyl one like in 7 prevents N-4 substitution. Cleavage of the third ring of 3b to give 3-benzylacyclovir 10 is an example of a new short route to 3-aralkyl-9-substituted guanines.     

Conformation of histidine model peptides. III. Chiroptical properties of cyclo-L-alanyl-L-histidine and cyclo-L-histidinyl-L-histidine

The chiroptical properties of the cyclic dipeptides cyclo-L -alanyl-L -histidine and cyclo-L -histidinyl-L -histidine have been investigated as a function of molecular conformation. The rotatory strengths of the n-π* transitions of the peptide chromophores and the lowest energy π-π* transitions of the imidazole chromophores have been calculated as a function of the angle of fold of the cyclic dipeptide group and the dihedral angles χ¹ and χ² of the amino acid side chains. The results of this investigation are consistent with the preferred position of the dihedral angle χ¹ occurring near 60° in the free base form of cyclo-L -alanyl-L -histidine, and near 180° when the imidazole side chain is protonated. Furthermore, in the case of the free base form of the imidazole group, it is possible that the tautomeric isomer in which N^ε is protonated may be more prevalent than the isomer in which N^δ is protonated.     

Linear dichroism studies of nucleic acids. III. Reduced dichoism curves of DNA in ethanol–water and in poly(vinyl alcohol) films

The uv linear dichroism of calf thylus DNA has been studied at different degrees of orientation both in flow-oriented ethanol–water solutions and in a stretched aqueous host of poly(vinyl alcohol) (PVA). The reduced dichroism (LD^R) curves in the region 250–290 nm for DNA in PVA films at 75 and 100% relative humidity (r.h.) are in fair agreement with the curves calculated for the A- and B-forms of DNA, based on the fiber structures and the π-π* transitions of the free bases. This suggests that DNA adopts its A and B conformations in PVA at 75 and 100% r.h. In ethanol, on the other hand, a deviation from the A-form spectrum shows that the conformation of DNA in the solution can differ from the fiber structure. At shorter wavelenghts, a positive contribution to LD^R is explained in terms of an out-of-plane polarized n-π* transition.     

Reductive Biotransformation of Benzaldehyde Derivatives by Baker's Yeast in Non-Conventional Media: Effect of Substrate Hydrophobicity on the Biocatalytic Reaction

The reduction of six derivatives of benzaldehyde, α,α,α-trifluorotolualdehyde, nitrobenzaldehyde, anisaldehyde, fluorobenzaldehyde, tolualdehyde, chlorobenzaldehyde, each of which was substituted in the ortho-, meta- and para-positions, was investigated in whole cell yeast biotransformations conducted in non-conventional media. Correlation between hydrophobic (π) and electronic (σ) parameters of the substituent of the substrate and biocatalytic activity in organic solvent media (hexane containing 2% v/v water) was evaluated. While catalytic activity in general decreased as the substituent hydrophobicity (π) increased, the trend was more pronounced for ortho- substituents compared to meta- and para-. When the electronic parameters (σ) of the meta- and para- substituents were correlated with the catalytic activity, the opposite was observed, namely the catalytic activity increased as the electronic parameter of the substituent increased. This observation was similar for meta- and para- substituents.

Preliminary studies on the relationships between solvent and substrate polarity on the one hand and catalytic activity on the other are also presented and discussed.