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Charge migration through DNA has been the focus of considerable interest in recent years. This book presents contributions from an international team of researchers active in this field. It contains a wide range of topics that includes the mathematical background of the quantum processes involved, the role of charge transfer in DNA radiation damage, a new approach to DNA sequencing, DNA photonics, and many others.
DNA sequences containing contiguous AA or TT mismatches, as well as sequences containing a 3-deazacytidine analogue were synthesized. Irradiation of anthraquinone abstracts an electron from the DNA. The loss of an electron from double-stranded DNA results in the formation of a radical cation that migrates through the DNA where it reacts irreversibly with H2O or O2 at GG steps. Subsequent treatment with piperidine or Fpg enzyme cleaves the backbone of the DNA at the site of reaction. DNA oligomers were designed to contain contiguous AA, TT, or G3-deazacytidine mismatches. It was revealed that the mismatches destabilize the duplex DNA; however, there is no measurable effect on the overall secondary structure of the DNA. The contiguous (AA)n mismatch, where n 7, was shown to have no effect on charge migration efficiency. In contrast, the contiguous (TT)n mismatch, where n 2, was shown to have near complete inhibition of charge migration through the mismatch region. Charge migration through the G3-deazacytidine mismatch was shown to have no effect on charge migration efficiency as well. Interestingly, reaction at the (G3-deazacytidine)2 base pairs revealed a change in the ratio of oxidative damage at the Gs. In (GC)2 base pairs, the ratio of damage at the two Gs is 10:1 with the majority of damage occurring at the 5-G. However, the (G3-deazacytidine)2 base pairs had an equal distribution of damage at the 5 and 3-Gs, with the amount of total reactivity equaling the (GC)2 base pairs. These findings indicate that the base composition in mismatched DNA determines the effect on charge migration efficiency and trapping reactivity.
DNA is the carrier of biological information and damage to DNA has been believed to be responsible for many diseases including aging and cancer. One electron oxidation by charge migration through DNA is one of the processes that lead to DNA damage. It is known that the guanine N1 imino proton can be transferred to the N3 of cytidine that is hydrogen bonded to it. Some reports have implication that this proton transfer and radical cation migration are coupled to each other. We have incorporated 5-fluoro-2'-deoxycytidine (F5dC) in place of normal dC in DNA duplexes. Although, the lower pKa of F5dC should perturb the proton transfer process from the guanine to it, we do not see any change in the charge migration ability compared to the strands having normal cytidines. However, there is a considerable decrease in the guanine damage, when there is F5dC opposite to it. These results indicate that the charge migration is not coupled with proton transfer process, but the change in basicity affects the reactivity of the guanine radical cation. We have also reported a systematic study on the charge migration through adenine (A) and thymidine (T) containing DNA strands. The damage has predominantly seen in thymidine, although from oxidation potentials reaction at adenine was expected. The thymidine reaction has been analyzed thoroughly. It has similar distance dependence property as the well known guanine damage. Study of thymidine damage in presence of radical scavengers, replacement of thymidines by Uracil and HPLC-MS study point toward reactions involving tandem lesion. On the basis of these information and molecular modeling study we have proposed a possible pathway leading to one-electron oxidation at the thymidines.
The past few years have witnessed intense research in this fascinating field as well as many controversial discussions. Now the time is ripe for a comprehensive book covering not only theoretical aspects, but also such mechanistic topics as principles and mechanisms of photoinduced charge injection, transport and trapping in DNA, sequence-dependent DNA dynamics, spectroscopic investigations of hole transport and much more. From the contents: * Principles and Mechanisms of Photoinduced Charge Injection, Transport and Trapping in DNA * Sequence-Dependent DNA Dynamics: The Regulator of DNA-Mediated Charge Transport * Excess Electron Transfer in DNA Probed with Flavin and Thymine Dimer Modified Oligonucleotides * Dynamics of Photoinitiated Hole and Electron Injection in Duplex DNA * Spectroscopic Investigation of Oxidative Hole Transfer via Adenine Hopping in DNA * Chemical Probing of Reductive Electron Transfer in DNA * Chemical Approach for Modulating Hole Transport in DNA * Spectroscopic Investigation of Charge Transfer in DNA * Spectroscopic Probing of Ultrafast Structural Relaxation and Electron Transfer Dynamics in DNA Edited by Hans-Achim Wagenknecht, and written by renowned international authors, this book provides an excellent overview with high quality contributions, making it a "must-have" for everyone working in the field.
with contributions by numerous experts
Charge transport and charge transfer (CT) capabilities of deoxyribonucleic acid (DNA) are investigated. A QM/MM multi-scale framework is applied to calculate the CT capabilities of DNA under conditions resembling the experimental setup. The simulations are able to explain and predict the outcome of experiments and therefore make suggestions in advance. Based on the findings, suitable DNA sequences can be opted for the design of DNA-based devices as nano-scale electronic elements.
Long-distance radical cation transport was studied in DNA condensates where linearized pUC19 plasmid was ligated to an oligomer and transformed into DNA condensates with spermidine. DNA condensates were detected by Dynamic Light Scattering and observed by Transmission Electron Microscopy. Introduction of charge into the condensates causes long-distance charge migration, which is detected by reaction at the remote guanines. The efficiency of charge migration in the condensate is significantly less than it is for the corresponding oligomer in solution. This result is attributed to a lower mobility for the migrating radical cation in the condensate, caused by inhibited formation of charge-transfer-effective states. Radical cation transport was also studied in DNA condensates made from an oligomer sandwiched between two linearized plasmids by double ligation. Unlike the single ligated plasmid condensates, the efficiency of charge migration in the double ligated plasmid-condensates is high, indicative of local structural and conformational transformation of the DNA duplexes. Organic monomer units having extended ð-conjugation as part of a long conducting polymer was synthesized and characterized. The monomer units were covalently attached to particular positions in DNA oligonucleotides by either the convertible nucleotide approach or by phosphoramidite chemistry. Successful attachment of the monomer units to DNA were confirmed by mass spectral analysis. The DNA-conjoined monomer units can self assemble in the presence of complementary sequences which act as templates that can control polymer formation and structure. By this method the para-direction of the polymer formation can be enforced and may be used to generate materials having nonrecurring, irregular structures.
Results of work by other investigators support the hypothesis that negative charge can migrate in DNA. Charge transfer between nucleotides and electron migration in solid state DNA has been demonstrated, with migration distances as great as 110 bases. Here we report a series of studies on aqueous solutions of DNA and oligonucleotides in which the radiolysis of 5-bromouracil (BU) substituted for thymine is used as a molecular probe to detect and measure the extent of electron migration. In studies using oligonucleotides, BU was substituted for thymine at specific locations in defined base sequences using automated phosphoramidite synthesis techniques. Using these single-stranded oligonucleotides with BU located at the 5 in. end of the sequence, electrons do not appear to migrate more than one base, if any.