Interactions between purine derivatives: Electronic spectral studies. II. Excition interactions in the dimer of 6-methylpurine in aqueous solution

From a study of the concentration dependence of the ultraviolet absorption spectra of aqueous solutions of 6-methylpurine, the spectra of monomeric and dimeric species have been derived. The dichroic spectrum of 6-methylpurine in stretched poly(vinyl alcohol) films has been determined. The absorption envelope of 6-methylpurine up to 44,000 cm^?1 appears to include a low-intensity nitrogen (π*,n) transition at the low wavenumber tail and two additional electronic transitions of dominant intensities. Both the experimental dichroic ratios and theoretical calculations suggest that the letter two transitions are in-plane (π*,π) types. Analysis of the dimer species spectrum in terms of exciton interactions between molecules in “sandwich” conformation has been carried out. The interaction between the moments of the lowest energy (π*,π) transitions of the molecule in the dimer seems to result in transfer rates of energy of the order of 10¹³ sec^?1 between the two molecules.     

Absorption of the flavin dimers

The electronic absorption spectra of the flavomononucleotide (FMN) in aqueous solution and in glycerine-water solution with change of the dye concentration have been measured. The FMN dimer absorption spectrum, monomer absorption spectrum, dimerization constant K and molar fraction of the monomer were calculated. It was found that FMN dimerization constants in aqueous solution were K_a = 118.0 l/mol and in glycerine K_g = 20.5 l/mol. In the region of the monomer absorption band two dimer absorption bands appear, in accordance with the Kasha molecular exciton theory.     

Spectroscopic investigations and hydrogen bond interactions of 8-aza analogues of xanthine, theophylline and caffeine: a theoretical study

The structure, spectral properties and the hydrogen bond interactions of 8-aza analogues of xanthine, theophylline and caffeine have been studied by using quantum chemical methods. The time-dependent density functional theory (TD-DFT) and the singly excited configuration interaction (CIS) methods are employed to optimize the excited state geometries of isolated 8-azaxanthine, 8-azatheophylline tautomers and 8-azacaffeine in both the gas and solvent phases. The solvent phase calculations are performed using the polarizable continuum model (PCM). The absorption and emission spectra are calculated using the time-dependent density functional theory (TD-DFT) method. The results from the TD-DFT calculations reveal that the excitation spectra are red shifted relative to absorption in aqueous medium. These changes in the transition energies are qualitatively comparable to the experimental data. The examination of molecular orbital reveals that the molecules with a small H→L energy gap possess maximum absorption and emission wavelength. The relative stability and hydrogen bonded interactions of mono and heptahydrated 8-azaxanthine, 8-azatheophylline tautomers and 8-azacaffeine have been studied using the density functional theory (DFT) and Møller Plesset perturbation theory (MP2) implementing the 6-311++G(d,p) basis set. The formation of strong N-H…O bond has resulted in the highest interaction energy among the monohydrates. Hydration does not show any significant impact on the stability of heptahydrated complexes. The atoms in molecule (AIM) and natural bonding orbital (NBO) analyses have been performed to elucidate the nature of the hydrogen bond interactions in these complexes.

The calculated circular dichroism of polyproline II in the polarizability approximation

The circular dichroism (CD) spectrum of polyproline II (PPII) has heretofore been moderately well calculated from exciton theory only at the expense of assuming unreasonable chain conformations and accepting a conservative spectrum in the 180–250-nm region (which is not observed). We have incorporated far uv transitions in the polarizability approximation and, together with the π₂π* transition, have calculated the resulting correction to the exciton model. This has been accompanied by a modified assignment of the ππ* transition in PPII, and a simultaneous calculation of the absorption and CD spectra of the α-helix, β structure, PPI, and PPII. We obtain good agreement with the observed CD spectrum of PPII in the 180–250-nm region for acceptable chain conformations. In addition, we predict a negative CD into the far uv, in agreement with recent experimental observations. Our calculations also reproduce features of the far uv CD spectrum of the α-helix, and are in agreement with the CD spectra of the β chain and PPI. The calculated CD of the unordered polypeptide chain is not significantly influenced by far uv contributions, indicating that our previous calculation is valid for such a system. These results demonstrate the importance of incorporating far uv transitions in order to achieve an adequate theoretical explanation of the CD spectra of polypeptides.     

On the influence of pigment-protein interactions on energy transfer processes in photosynthetic membrane structures. 3. The FMO complex of Chlorobium tepidum at high pressure

The low-temperature absorption spectra of the Chlorobium tepidum FMO bacteriochlorophyll-protein complex at various pressures have been calculated within the framework of mini-exciton theory. The dependences of the Qy transition energies of the monomeric pigments on pressure have been found by means of functional minimization. This functional includes the parameters of both theoretical and experimental absorption spectra at low temperatures and various pressures. The dependences obtained are compared with those derived for the exciton transition energies, which have been obtained by deconvoluting absorption spectra with seven Gaussian components at each pressure. The pressure increase has been shown to result in the increased coupling energy between both the pigment molecules themselves and pigments and amino acid residues. The pigment molecules capable of binding histidines and water molecules have been shown to have the greatest and smallest responses to increased pressure, respectively. The couplings of Bchl molecules with the surrounding amino acid residues have been shown to change both the exciton delocalization index and the exciton distribution between the pigment molecules within the protein subunit; the increased pressure does not change these parameters significantly.     

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.     

Red Chlorophylls in the Exciton Model of Photosystem I

Structural arrangement of pigment molecules of Photosystem I of photosynthetic cyanobacterium Synechococcus elongatus is used for theoretical modeling of the excitation energy spectrum. It is demonstrated that a straightforward application of the exciton theory with the assumption of the same molecular transition energy does not describe the red side of the absorption spectrum. Since the inhomogeneity in the molecular transition energies caused by a dispersive interaction with the molecular surrounding cannot be identified directly from the structural model, the evolutionary search procedure is used for fitting the low temperature absorption and circular dichroism spectra. As a result, one dimer, three trimers and one tetramer of chlorophyll molecules responsible for the red side of the absorption spectrum with their assignment to the spectroscopically established three bands at 708, 714 and 719 nm are determined. All of them are found to be situated not in the very close vicinity of the reaction center but are encircling it almost at the same distance. In order to explain the unusual broadening on the red side of the spectrum the exciton state mixing with the charge transfer (CT) states is considered. It is shown that two effects can be distinguished as caused by mixing of those states: (i) the oscillator strength borrowing by the CT state from the exciton transition and (ii) the borrowing of the high density of the CT state by the exciton state. The intermolecular vibrations between two counter-charged molecules determine the high density in the CT state. From the broad red absorption wing it is concluded that the CT state should be the lowest state in the complexes under consideration. Such mixing effect enables resolving the diversity in the molecular transition energies as determined by different theoretical approaches.     

Heparin: New Biochemical and Medical Aspects : Proceedings of the Symposium of the Deutsche Gesellschaft für Klinische Chemie,Titisee, Breisgau,German Federal Republic,June 29th - July 1st, 1981 Edited by I. Witt Walter de Gruyter; Berlin,New York, 1983 372 pages. DM 155.00

Using a phosphoroscopic attachment to the dichrograph, light-induced circular dichroism spectra have been measured for chlorophyll-protein complexes of Photosystem I. Minor components at 672, 678 and 685 nm are observed in these spectra in addition to the components of dimer splitting of the P700 Q_y transition at 691 and 698 nm. The minor components are due to the Chl672, Chl₆₇₈ and Chl₆₈₅ forms of antenna chlorophylls, the optical activity of which is changed 2–4% as a result of P700 oxidation. It is suggested that P700 is not an isolated dimer but that it is included in a local complex comprising 8–10 chlorophyll molecules with an exciton level splitting value of 120–140 cm^?1.     

Structure and electronic absorption spectra of nematogenic alkoxycinnamic acids - a comparative study based on semiempirical and DFT methods

Structure of nematogenic p-n-Alkoxy cinnamic acids (nOCAC) with various alkyl chain carbon atoms (n = 2, 4, 6, 8) has been optimized using density functional B3LYP with 6-31+G (d) basis set using crystallographic geometry as input. Using the optimized geometry, electronic structure of the molecules has been evaluated using the semiempirical methods and DFT calculations. Molecular charge distribution and phase stability of these systems have been analyzed based on Mulliken and L?wdin population analysis. The electronic absorption spectra of nOCAC molecules have been simulated by employing DFT method, semiempirical CNDO/S and INDO/S parameterizations. Two types of calculations have been performed for model systems containing single and double molecules of nOCAC. UV-Visible spectra have been calculated for all single molecules. The UV stability of the molecules has been discussed in light of the electronic transition oscillator strength (f). The dimer complexes of higher homologues (n = 6, 8) have also been reported to enable the comparison between single and double molecules.     

Electronic spectra and fluorescence properties of multichromophoric sulfonylureas

The multichromophoric character of two sulfonylurea herbicides, SMT and BNS, has been investigated in its manifestations in the electronic absorption spectra and in some fluorescence properties through a combined experimental and theoretical approach. After a theoretical analysis of the most stable structures of these flexible systems, the UV absorption spectra of the two multichromophoric compounds have been analysed both experimentally and theoretically, and most transitions have been assigned to individual chromophores, also by comparison with four suitable reference compounds (5-8). Finally, some experimental information concerning the fluorescence spectra and quantum yields have been analysed with reference to the contributions from single fluorophores and the role of low-lying n → π^∗ states.     

Electronic transition moments of 6-methyl isoxanthopterin—a fluorescent analogue of the nucleic acid base guanine

Fluorescent nucleic acid base analogues are important spectroscopic tools for understanding local structure and dynamics of DNA and RNA. We studied the orientations and magnitudes of the electric dipole transition moments (EDTMs) of 6-methyl isoxanthopterin (6-MI), a fluorescent analogue of guanine that has been particularly useful in biological studies. Using a combination of absorption spectroscopy, linear dichroism (LD) and quantum chemical calculations, we identified six electronic transitions that occur within the 25 000–50 000 cm⁻¹ spectral range. Our results indicate that the two experimentally observed lowest-energy transitions, which occur at 29 687 cm⁻¹ (337 nm) and 34 596 cm⁻¹ (289 nm), are each polarized within the plane of the 6-MI base. A third in-plane polarized transition is experimentally observed at 47 547 cm⁻¹ (210 nm). The theoretically predicted orientation of the lowest-energy transition moment agrees well with experiment. Based on these results, we constructed an exciton model to describe the absorption spectra of a 6-MI dinucleotide–substituted double-stranded DNA construct. This model is in good agreement with the experimental data. The orientations and intensities of the low-energy electronic transitions of 6-MI reported here should be useful for studying local conformations of DNA and RNA in biologically important complexes.     

Electronic and molecular structure of M-DNA fragments

To study M-DNA molecular structure (such DNA with transition metal ions placed between the nucleic bases is able to conduct the electric current) and its conductivity mechanisms, we carried out ab initio quantum-mechanical calculations of electronic and spatial structures, thermodynamic characteristics of adenine-thymine (АТ) and guanine-cytosine (GC) base pair complexes with Zn²⁺ and Ni²⁺. To take into account the influence of the alkaline environment, calculations for these complexes were also carried out with hydroxyl and two water molecules. Computations were performed at MP2 level of theory using 6–31+G* basis set. Analogous calculations were carried out for (AC)(TG) stacking dimer of nucleic acid base pairs with two Zn²⁺. The calculation of the interaction energy in complexes has shown the preference of locating the metal ion (instead of the imino proton) between bases in M-DNA. The electronic transition energy calculation has revealed the reduction of the first singlet transition energy in АТ and GC complexes with Ni²⁺ from 4.5 eV to 0.4 - 0.6 eV. Ni²⁺ orbitals take part in the formation of HOMO and LUMO on the complexes investigated. It was shown that charges of metal ions incorporated into complexes with nucleic bases and in dimer decrease significantly.     

Electronic and vibrational exciton coupling in oxidized trianglimines

Readily available chiral trianglimine and their (poly)oxygenated congeners represent a unique class of macrocyclic rigid compounds optimal for testing electronic and vibrational circular dichroism exciton chirality methods. Electronic and vibrational circular dichroism spectra of such trianglimines are strongly affected by polar substituents in macrocycle skeletons. Double substitution by OH groups in each aromatic fragment of the macrocycle causes sign reversal of the exciton couplet in the region of the strongest UV absorption. On the other hand, electronic circular dichroism spectrum of the macrocycle having 2 methoxy groups shows 2 exciton couplets—the long‐wavelength positive and the second of the negative sign, observed at the shorter wavelengths. VCD spectra of macrocyclic imines show vibrational exciton couplets in the region of strong C=N stretches. The signs of these couplets are positive and the opposite of the diamine chirality. For trianglimine macrocycles the interpretation of VCD spectra in terms of excitons is much more convincing than for electronic circular dichroism spectra. By contrast, trans‐1,2‐diaminocyclohexane–based vicinal diimines, being a one‐third of the respective macrocycle, do not exhibit any vibrational exciton effect. Experimental data were confronted with DFT calculations. We observed good‐to‐excellent agreement between experimental and computed data.     

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.     

Exciton coupling between enones: Quassinoids revisited

The electronic circular dichroism (ECD) spectra of two previously reported quassinoids containing a pair of enone chromophores are revisited to gain insight into the consistency and applicability of the exciton chirality method. Our study is based on time‐dependent Density Functional Theory calculations, transition and orbital analysis, and numerical exciton coupling calculations. In quassin ( 1 ) the enone/enone exciton coupling is quasi‐degenerate, yielding strong rotational strengths that account for the observed ECD spectrum in the enone π‐π* region. In perforalactone C ( 2 ) the nondegenerate coupling produces weak rotational strengths, and the ECD spectrum is dominated by other mechanisms of optical activity. We remark the necessity of a careful application of the nondegenerate exciton coupling method in similar cases.     

Theoretical optical properties of poly-L-proline

A non-perturbational technique is used to calculate the circular dichroism and absorption spectra of polypeptide chains having conformations similar to that of poly-L -proline II. The method employs a Bogoliubov exciton formalism, from which the various optical terms associated with parallel and perpendicular components of the exciton band are obtained. A simple model for the peptide unit, consisting of three Gaussian absorption bands, leads to reasonable results for the polymer spectra, provided the lowest energy peptide π → π* transition is taken at 207 mμ and the value of the Ramachandran angle Ψ is taken to be 390°. The calculations suggest that the polymer circular dichroism spectrum is the resultant of strong interference among the two Gaussian exciton terms and the non-Gaussian helix term. Consequently, the CD spectrum is very sensitive to the value of Ψ. It is found that the small positive CD band in the vicinity of 230 mμ arises partly from the effect of the static (crystal) field interactions on the n → π* CD band.     

The flavin dimers I. The application of absorption in anti-stokes excitation region to investigate the flavin dimer formation

The dimer formation process of the flavin in aqueous solution has been studied. The difference absorption spectra with the change of concentration in Stokes and anti-Stokes excitation region of the flavomononucleotide and riboflavin were measured. The highest temperature in which the dimers still appear is discussed. It is suggested that this temperature T_d can be treated as one of the empirical parameters which describe the dimer formation process of the dyes in solutions. The aqueous solution of flavins with the concentration c?5·10^?5 M at room temperature can be treated as a flavin monomers solution. For higher concentrations the flavin monomers and dimers exist in a solution at room temperature.     

A study of the spectral and luminescence manifestations of the aggregation of thymine chromophores in polythymidylic acid aqueous solutions at room temperature in the context of photochemical information recording using thymine

The luminescence and excitation spectra of polythymidylic acid aqueous solutions at room temperature were studied. In addition to the previously described band at 338 nm, two new bands at 320 and 350 nm were recorded at various excitation wavelengths. An examination of the excitation spectra that had not been studied previously, as well as their comparison with the differential absorption spectra previously recorded during photodimerization, allowed us to interpret the band at 320 nm as the band of noninteracting chromophores; the band at 338 nm as the band of the most photochemically active, densely packed stacking dimmers (exciton splitting of absorption band of ～4000 cm^?1); and the band at 350 nm as the band of photochemically inactive large stacking aggregates (n ≥ 10, exciton splitting of ～8000 cm^?1). The changes in the optical density of the polythymidylic acid aqueous solution at γ = 270 nm after successive irradiation of the solution with light at 279 + 302 and 248 nm were studied. The reasons for their incomplete reversibility are discussed.     

The metallochromic indicator dye Arsenazo III forms 1: 1 complexes with caffeine

The metallochromic indicator dye, Arsenazo III, forms a 1:1 complex with caffeine, a methylxanthine. Binding is accompanied by a wavelength-dependent shift in the absorption spectrum of the dye. The magnitude of the absorption change is significant at wavelengths typically used to monitor intracellular calcium ion. The equilibrium constant for the caffeine-dye reaction is approx. 20 mM. The complex has a differential molar extinction coefficient of ?5.05 · 10³ M^?1 · cm^?1 at 630 nm.     

Spectral manifestations of conformation heterogeneity of a cytidine dinucleotide. A fraction with strong exciton base-base interaction

The absorption, emission and excitation luminescence spectra of CpCp have been studied in comparison with the same of Cp at 77K in the glass mixture (ethyleneglycol: water, 1:1, v/v). It is shown, that the CpCp fluorescence is of dual nature: eximer and exciton. The exciton absorption spectrum with split band (3000 cm-1) has been calculated by means of the fluorescence exciton spectrum. It corresponds to the "conservative" part of the CD spectrum.