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Conclusion
of DNA.Here, the amount of water and the content of counterions necessary to
support a helical double-stranded structure in the simulationswas characterized.
Upon removal of water from the molecule the helical structure of DNA under-
wentmarked changes. Finally, the double strand lost its helical character roughly
at 6watermolecules per phosphate group. Continued drying induced a rupture
ofhydrogenbondsandacollapseof thedouble-strandedstructure toadisordered
compactcoil. Atfist sight, thiswasadevastatingobservationwithregardto theex-
perimental setup. Providentially, the simulations showed that thehelical structure
ofmicrohydratedDNA can be supported by pulling at the 3’-ends, which again
resembles the experimental setup.
The furtherpullingat the3’-endsof theDNAstrands lead toDNAconformations
already observed in previous studies. In this work, a crucial dependence on the
applied pulling rate was shown for the conformational change from a helix-like
to a ladder-like DNA structure. This illustrates the irreversibility of the stretch-
ing process in the simulations, when the pulling is several orders of magnitude
faster than inexperiments. Toovercome this issue, the investigationofCT in those
stretchedDNAconformationswasperformedonstructuresheldat certain lengths
duringsimulation time, rather thancalculatingalongnon-equilibriumpullingsim-
ulations.
The first charge transport calculations in this work were performed on DNA in
stretched conformations. Here, the efficiency of hole transport in the studied ds-
DNA oligomers was little affected by stretching of the molecule by up to 10%
of the free length. When theDNAmolecule is stretched further, the response of
CT efficiency is determined by the exact nucleobase sequence. In detail, the con-
formational change lead to a breaking point, where the distance between certain
base-pair steps increases largely. Therefore, theoverallCTefficiencydrops steeply
in the exactmoment thefist conformational transitionoccurs.
These results provide a means for the interpretation of the outcome of conduc-
tivity experimentswhere theDNAmolecule is stretched and theDNAsequences
resemble those simulated. The accumulated knowledgemakes it possible to con-
structDNAsequences such that the extent towhich their conductivity is affected
by themechanical stressduring the experiments is controlled. Also, suitableDNA
sequences canbeopted for in thedesignofDNA-baseddevicesasnano-scale elec-
tronic elements,where limiteddependenceof conductivityon length isdesirable.
106
Charge Transport in DNA
Insights from Simulations
- Titel
- Charge Transport in DNA
- Untertitel
- Insights from Simulations
- Autor
- Mario Wolter
- Verlag
- KIT Scientific Publishing
- Datum
- 2013
- Sprache
- englisch
- Lizenz
- CC BY-SA 3.0
- ISBN
- 978-3-7315-0082-7
- Abmessungen
- 17.0 x 24.0 cm
- Seiten
- 156
- Schlagwörter
- Charge Transport, Charge Transfer, DNA, Molecular Dynamics, Quantum Mechanics
- Kategorien
- Naturwissenschaften Chemie
Inhaltsverzeichnis
- Zusammenfassung 1
- Summary 3
- 1 Introduction 5
- 2 TheoreticalBackground 11
- 3 SimulationSetup 39
- 4 DNAUnderExperimentalConditions 49
- 5 ChargeTransport inStretchedDNA 69
- 6 ChargeTransport inMicrohydratedDNA 79
- 7 AParametrizedModel toSimulateCT inDNA 89
- 8 Conclusion 105
- Appendix 111
- A DNAUnderExperimentalConditions 111
- B CTinMicrohydratedDNA 117
- List ofPublications 137