Stephan Hess scite author profile

From previous thermal and photoinduced charge-transfer reactions in duplex DNA there is accumulative evidence for an attenuation parameter beta of the distance dependence in the range 0.6-0.8 A(-1), with the exception of one specific system exhibiting beta = 1.5 A(-1) which is reinvestigated in this paper. Femtosecond to nanosecond time-resolved pump-probe spectroscopy has been used to follow photoinduced charge-shift dynamics in DNA duplexes containing a covalently appended, protonated 9-alkylamino-6-chloro-2-methoxyacridine chromophore. This acridine derivative (X+) resides in the DNA duplex at a specific abasic site, which is highly defined as reflected in the monoexponentiality of the kinetics. In the presence of only neighboring A:T base pairs, no charge transfer occurs within the excited-state lifetime (18 ns) of the chromophore. However, the presence of a guanine nucleobase as either a nearest neighbor or with one interspersed A:T base pair does result in fluorescence quenching. In the case of nearest neighbors, the intermediate radical state X* is formed within 4 ps and decays on the 30 ps time scale. Placing one A:T base pair between the X+ and guanine slows down the forward transfer rate by 3 orders of magnitude, corresponding to an apparent beta value of >2.0 A(-1). This dramatic decrease in the rate is due to a change in charge-transfer mechanism from a (nearly) activationless to a thermally activated regime in which the forward transfer is slower than the back transfer and the X* state is no longer observed. These observations indicate that the distance dependence of charge injection in the X+-labeled DNA duplex is not solely caused by a decrease in electronic couplings but also by a concomitant increase of the activation energy with increasing distance. This increase in activation energy may result from the loss of driving force due to excited-state relaxation competing with charge transfer, or reflect distance-dependent changes in the energetics, predominantly of the low-frequency reorganization energy in this charge-shift reaction, on purely electrostatic grounds. To test the hypothesis of distance-dependent activation energy, guanine has been replaced by 7-deazaguanine, its easier-to-oxidize purine analogue. In these duplexes, a similar change of charge-transfer mechanism is found. However, consistent with an a priori larger driving force this change occurs at a larger donor-acceptor separation than in the X+-guanine systems. Independent of the detailed contributions to the distance-dependent activation energy, this phenomenon illustrates the complex nature of experimental beta values.

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Distance-Dependent Activation Energies for Hole Injection from Protonated 9-Amino-6-chloro-2-methoxyacridine into Duplex DNA

Davis

Hess

Naydenova

et al. 2002

J. Am. Chem. Soc.

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The recent investigation of the apparently anomalous attenuation factor (beta > 1.5 A(-1)) for photoinduced hole injection into DNA duplexes modified by protonated 9-amino-6-chloro-2-methoxyacridine (X+) led to the conclusion that in addition to the electronic couplings, the activation energy must also be distance-dependent. In this communication we report the verification of this postulate by direct measurements of the activation energies for a series of (X+)-modified DNA duplexes which sample an appreciable range of donor-acceptor distances (approximately 4-11 A). The resulting changes in thermal activation energy can be explained within the framework of a distance-dependent reorganization energy.

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Ultrafast Electron Transfer in the Complex between Fluorescein and a Cognate Engineered Lipocalin Protein, a So-Called Anticalin

et al. 2002

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Anticalins are a novel class of engineered ligand-binding proteins with tailored specificities derived from the lipocalin scaffold. The anticalin FluA complexes fluorescein as ligand with high affinity, and it effects almost complete quenching of its steady-state fluorescence. To study the underlying mechanism, we have applied femtosecond absorption spectroscopy, which revealed excited-state electron transfer within the FluA‚Fl complex to be responsible for the strong fluorescence quenching. On the basis of a comparison of redox potentials, either tryptophan or tyrosine may serve as electron donor to the bound fluorescein group in its excited singlet state, thus forming the fluorescein trianion radical within 400 fs. The almost monoexponential rate points to a single, well-defined binding site, and its temperature independence suggests an (almost) activationless process. Applying conventional electron transfer theory to the ultrafast forward and slower back-rates, the resulting electronic interaction is rather large, with ∼140 cm -1 for tyrosine, which would be consistent with a coplanar arrangement of both aromatic moieties within van der Waals distance. The weak residual steady-state fluorescence originates from a small (∼10%) component with a time constant in the 40-60 ps range. These results demonstrate the power of timeresolved absorption spectroscopy as a diagnostic tool for the elucidation of a fluorescence quenching mechanism and the temporal profiles of the processes involved. The high structural and dynamic definition of the complexation site suggests the anticalin FluA to be a promising model in order to tailor and probe electronic interactions and energetics in proteins. † M.E.M.-B. gratefully acknowledges financial support by the Deutsche Forschungsgemeinschaft (SFB 533) and the Volkswagenstiftung. A.S. thanks the Fonds der Chemischen Industrie for financial support.

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Stephan Hess

On the Apparently Anomalous Distance Dependence of Charge-Transfer Rates in 9-Amino-6-chloro-2-methoxyacridine-Modified DNA

Distance-Dependent Activation Energies for Hole Injection from Protonated 9-Amino-6-chloro-2-methoxyacridine into Duplex DNA

Ultrafast Electron Transfer in the Complex between Fluorescein and a Cognate Engineered Lipocalin Protein, a So-Called Anticalin

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