The scope of this review is the nature and dynamics of the singlet excited electronic states created in nucleic acids and their constituents by UV light. Interest in the UV photochemistry of nucleic acids has long been the motivation for photophysical studies of the excited states, because these states are at the beginning of the complex chain of events that culminates in photodamage. UV-induced damage to DNA has profound biological consequences, including photocarcinogenesis, a growing human health problem.1-3 Sunlight, which is essential for life on earth, contains significant amounts of harmful UV (λ < 400 nm) radiation. These solar UV photons constitute one of the most ubiquitous and potent environmental carcinogens. This extraterrestrial threat is impressive for its long history; photodamage is as old as life itself. The genomic information encoded by these biopolymers has been under photochemical attack for billions of years. It is not surprising then that the excited states of the nucleic acid bases (see Chart 1), the most important UV chromophores of nucleic acids, are highly stable to photochemical decay, perhaps as a result of selection pressure during a long period of molecular evolution. This photostability is due to remarkably rapid decay pathways for electronic energy, which are only now coming into focus through femtosecond laser spectroscopy. The recently completed map of the human genome and the ever-expanding crystallographic database of nucleic acid structures are two examples that illustrate the richly detailed information currently available about the static properties of nucleic acids. In contrast, much less is known about the dynamics of these macromolecules. This is particularly true of the dynamics of the excited states that play a critical role in DNA photodamage. Efforts to study nucleic acids by time-resolved spectroscopy have been stymied by the apparent lack of suitable fluorophores. In contrast, dynamical spectroscopy of proteins has flourished thanks to intrinsically fluorescent amino acids such as tryptophan, tyrosine, and phenylalanine.4 The primary UVabsorbing constituents of nucleic acids, the nucleic acid bases, have vanishingly small fluorescence quantum yields under physiological conditions of temperature and pH.5 In fact, the bases were frequently described as “nonfluorescent” in the early literature. * To whom correspondence should be addressed. E-mail: kohler@ chemistry.ohio-state.edu. Phone: (614) 688-3944. Fax: (614) 2921685. 1977 Chem. Rev. 2004, 104, 1977−2019

Ultrafast Excited-State Dynamics in Nucleic Acids

Ultraviolet light is strongly absorbed by DNA, producing excited electronic states that sometimes initiate damaging photochemical reactions. Fully mapping the reactive and nonreactive decay pathways available to excited electronic states in DNA is a decades-old quest. Progress toward this goal has accelerated rapidly in recent years, in large measure because of ultrafast laser experiments. Here we review recent discoveries and controversies concerning the nature and dynamics of excited states in DNA model systems in solution. Nonradiative decay by single, solvated nucleotides occurs primarily on the subpicosecond timescale. Surprisingly, excess electronic energy relaxes one or two orders of magnitude more slowly in DNA oligo- and polynucleotides. Highly efficient nonradiative decay pathways guarantee that most excited states do not lead to deleterious reactions but instead relax back to the electronic ground state. Understanding how the spatial organization of the bases controls the relaxation of excess electronic energy in the double helix and in alternative structures is currently one of the most exciting challenges in the field.

DNA Excited-State Dynamics: From Single Bases to the Double Helix

The CH/π hydrogen bond is an attractive molecular force occurring between a soft acid and a soft base. Contribution from the dispersion energy is important in typical cases where aliphatic or aromatic CH groups are involved. Coulombic energy is of minor importance as compared to the other weak hydrogen bonds. The hydrogen bond nature of this force, however, has been confirmed by AIM analyses. The dual characteristic of the CH/π hydrogen bond is the basis for ubiquitous existence of this force in various fields of chemistry. A salient feature is that the CH/π hydrogen bond works cooperatively. Another significant point is that it works in nonpolar as well as polar, protic solvents such as water. The interaction energy depends on the nature of the molecular fragments, CH as well as π-groups: the stronger the proton donating ability of the CH group, the larger the stabilizing effect. This Perspective focuses on the consequence of this molecular force in the conformation of organic compounds and supramolecular chemistry. Implication of the CH/π hydrogen bond extends to the specificity of molecular recognition or selectivity in organic reactions, polymer science, surface phenomena and interactions involving proteins. Many problems, unsettled to date, will become clearer in the light of the CH/π paradigm.

The CH/π hydrogen bond in chemistry. Conformation, supramolecules, optical resolution and interactions involving carbohydrates

Multiconfiguration Self-Consistent Field and Multireference Configuration Interaction Methods and Applications

Intersystem crossing (ISC), formally forbidden within nonrelativistic quantum theory, is the mechanism by which a molecule changes its spin state. It plays an important role in the excited state decay dynamics of many molecular systems and not just those containing heavy elements. In the simplest case, ISC is driven by direct spin–orbit coupling between two states of different multiplicities. This coupling is usually assumed to remain unchanged by vibrational motion. It is also often presumed that spin-allowed radiationless transitions, i.e. internal conversion, and the nonadiabatic coupling that drives them, can be considered separately from ISC and spin–orbit coupling owing to the vastly different time scales upon which these processes are assumed to occur. However, these assumptions are too restrictive. Indeed, the strong mixing brought about by the simultaneous presence of nonadiabatic and spin–orbit coupling means that often the spin, electronic, and vibrational dynamics cannot be described independe...

Spin-Vibronic Mechanism for Intersystem Crossing

Radiationless deactivation pathways of excited gas phase nucleobases were investigated using mass-selected femtosecond resolved pump-probe resonant ionization. By comparison between nucleobases and methylated species, in which tautomerism cannot occur, we can access intrinsic mechanisms at a time resolution never reported so far (80 fs). At this time resolution, and using appropriate substitution, real nuclear motion corresponding to active vibrational modes along deactivation coordinates can actually be probed. We provide evidence for the existence of a two-step decay mechanism, following a 267 nm excitation of the nucleobases. The time resolution achieved together with a careful zero time-delay calibration between lasers allow us to show that the first step does correspond to intrinsic dynamics rather than to a laser cross correlation. For adenine and 9-methyladenine a first decay component of about 100 fs has been measured. This first step is radically increased to 200 fs when the amino group hydrogen atoms of adenine are substituted by methyl groups. Our results could be rationalized according to the effect of the highly localized nature of the excitation combined to the presence of efficient deactivation pathway along both pyrimidine ring and amino group out-of-plane vibrational modes. These nuclear motions play a key role in the vibronic coupling between the initially excited pipi(*) and the dark npi(*) states. This seems to be the common mechanism that opens up the earlier phase of the internal conversion pathway which then, in consideration of the rather fast relaxation times observed, would probably proceed via conical intersection between the npi(*) relay state and high vibrational levels of the ground state.

Excited states dynamics of DNA and RNA bases: characterization of a stepwise deactivation pathway in the gas phase.

Excited state dynamics of DNA and RNA bases: Characterization of a stepwise deactivation pathway in the gas phase

Combining laser desorption with a supersonic expansion together with the selectivity of IR/UV double resonance spectroscopy makes it possible to isolate and characterise the gas phase of remarkable backbone conformations of short peptide chains mimicking protein segments. A systematic bottom-up approach involving a conformer-specific IR study of peptide sequences of increasing sizes has enabled us to map the spectral signatures of the intramolecular interactions, which shape the peptide backbone, in particular H-bonds. The precise data collected are directly comparable to the most sophisticated quantum chemistry calculations of these species and therefore constitute a stringent test for the theoretical methods used. One-residue chains reveal the local conformational preference of the backbone and its dependence upon the nature of the residue. The investigation of longer chains provides evidence for a competition between simple successions of local conformational preferences along the chain and more folded structures, in which a new H-bonding network, involving distant H-bonding sites along the backbone, takes place. From three residues, the issue of helical folding can also be addressed. The present review of the gas phase literature data emphasizes the observation of remarkable secondary structures of biology, including short segments of β-strands, γ- and β-turns, combinations of turns, including a 310 helix. It also provides evidence for the flexibility of the peptide chains, i.e., a critical influence of rather minor interactions (like side-chain/backbone interactions) on the conformational stability. Finally, the paper will discuss future promising directions of the present approach.

Probing the competition between secondary structures and local preferences in gas phase isolated peptide backbones

The present IR−UV depletion spectroscopic study extends the recent data of literature by providing evidence for the existence of a fourth form of guanine in the gas phase. The comparison of the UV and IR signatures of the four forms together with those of the 7- and 9-methylated derivatives allows us to build up a new assignment in terms of enol/keto and 7/9NH tautomerisms. From this complete picture, it turns out that the UV spectroscopy of free guanine is mainly controlled by the 7/9NH tautomerism:  both 7NH tautomers observed are red-shifted compared to the 9NH ones, with the following origin transition order, from red to blue:  7NH enol (32864 ± 5 cm-1), 7NH keto (+405 cm-1), 9NH keto (+1046 cm-1), and 9NH enol (+1891 cm-1); 7-, 9- or 1-methylations are found to cause only moderate red shifts (less than 400 cm-1). The opposite trend is observed for the IR spectroscopy, which appears to be essentially controlled by the enol/keto tautomerism. This study exemplifies the need for cross-checked experimenta...

Tautomerism of the DNA Base Guanine and Its Methylated Derivatives as Studied by Gas-Phase Infrared and Ultraviolet Spectroscopy

In light of a recently published study on the IR spectroscopy of guanine in He droplets (Choi, M. Y.; Miller, R. E. J. Am. Chem. Soc. 2006, 128, 7320), the present letter proposes a new interpretation of the resonant two-photon ionization (R2PI) experiments on gas phase guanine, which is supported by quantum chemistry calculations. Whereas He droplet experiments detect the most stable forms, only one of these forms is observed (very marginally) in the R2PI spectrum, which is actually dominated by three less stable "rare" tautomers, whose stabilities lie in the 3-7 kcal/mol range. The absence of the most stable forms in the R2PI spectrum suggests that a tautomer-dependent ultrafast relaxation process takes place in the excited state of these stable tautomers. The present reinterpretation modifies qualitatively the picture of the excited state of guanine tautomers and should contribute to the understanding of the deactivation mechanisms taking place in the excited state of DNA bases.

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François Piuzzi

Papers

Excited states dynamics of DNA and RNA bases: characterization of a stepwise deactivation pathway in the gas phase.

Excited state dynamics of DNA and RNA bases: Characterization of a stepwise deactivation pathway in the gas phase

Probing the competition between secondary structures and local preferences in gas phase isolated peptide backbones

Tautomerism of the DNA Base Guanine and Its Methylated Derivatives as Studied by Gas-Phase Infrared and Ultraviolet Spectroscopy

Near-UV resonant two-photon ionization spectroscopy of gas phase guanine: evidence for the observation of three rare tautomers.