Designing Molecular Switches Based on DNA-Base Mispairing

Jissy, A. K.; Datta, Ayan

doi:10.1021/jp106732u

Cited by 55 publications

(66 citation statements)

References 76 publications

(69 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Temperature driven DNA switches might give an easier reversible control to molecular operations than the pH driven switches that have been suggested in the literature. 40 Despite that mesoscopic DNA models are not yet sufficiently accurate for very reliable quantitative predictions, the qualitative trend that we predict based on relative denaturation rates is an interesting phenomenon that deserves experimental efforts to test it. However, measuring denaturation rates of dsDNA is an experimental tour-de-force.…”

Section: A Dsdna Chainsmentioning

confidence: 85%

Mesoscopic modeling of DNA denaturation rates: Sequence dependence and experimental comparison

Dahlen

Erp

2015

The Journal of Chemical Physics

View full text Add to dashboard Cite

Using rare event simulation techniques, we calculated DNA denaturation rate constants for a range of sequences and temperatures for the Peyrard-Bishop-Dauxois (PBD) model with two different parameter sets. We studied a larger variety of sequences compared to previous studies that only consider DNA homopolymers and DNA sequences containing an equal amount of weak AT-and strong GC-base pairs. Our results show that, contrary to previous findings, an even distribution of the strong GC-base pairs does not always result in the fastest possible denaturation. In addition, we applied an adaptation of the PBD model to study hairpin denaturation for which experimental data are available. This is the first quantitative study in which dynamical results from the mesoscopic PBD model have been compared with experiments. Our results show that present parameterized models, although giving good results regarding thermodynamic properties, overestimate denaturation rates by orders of magnitude. We believe that our dynamical approach is, therefore, an important tool for verifying DNA models and for developing next generation models that have higher predictive power than present ones. C 2015 AIP Publishing LLC. [http://dx

show abstract

Section: A Dsdna Chainsmentioning

confidence: 85%

Mesoscopic modeling of DNA denaturation rates: Sequence dependence and experimental comparison

Dahlen

Erp

2015

The Journal of Chemical Physics

View full text Add to dashboard Cite

show abstract

“…Notably, that while it is known that DNA double helix contains the canonical Watson–Crick base pairs, which provides storage and precise transfer of the genetic information, their replacement with the non‐Watson–Crick base pairs leads to perspective interesting practical applications …”

Section: Introductionmentioning

confidence: 99%

Unexpected A·T(WC)↔A·T(rWC)/A·T(rH) and A·T(H)↔A·T(rH)/A·T(rWC) conformational transitions between the classical A·T DNA base pairs: A QM/QTAIM comprehensive study

Brovarets’

Tsiupa

Hovorun

2018

Int J of Quantum Chemistry

View full text Add to dashboard Cite

In this study, using QM/QTAIM calculations in the continuum with ε = 1 under normal conditions, we have revealed for the first time the nondissociative A·T(WC)↔A·T(rWC)/A·T(rH) and A·T(H)↔A·T(rH)/A·T(rWC) conformational transitions. It was established that they proceed via the essentially nonplanar transition states (С1 symmetry) through the intermediates, which are wobbled conformers (С1 symmetry) theoretically predicted in our previous work (Brovarets’ et al., Frontiers in Chemistry, 2018, 6:8, 10.3389/fchem.2018.00008) of the classical А·Т DNA base pairs—Watson–Crick А·Т(WC), reverse Watson–Crick А·Т(rWC), Hoogsteen А·Т(Н) and reverse Hoogsteen А·Т(rН). At this, the A·T(H)↔A·T(rWC) and A·T(WC)↔A·T(rH) conformational transformations are controlled by the transition states (TSs) stabilized by the participation of the intermolecular (T)N3H···N6(A) H‐bond (∼3.70 kcal·mol−1) between the imino group N3H of T and pyramidilized amino group N6H2 of A. Gibbs free energies of activation for these processes consist 12.22 and 11.11 kcal·mol−1, accordingly, under normal conditions. TSs, which control the A·T(WC)↔A·T(rWC) and A·T(H)↔A·T(rH) conformational transitions are stabilized by the participation of the intermolecular (T)N3H···N6(A) H‐bond (5.82 kcal·mol−1) and bifurcating intermolecular (T)N3H···N6(A) (5.00) and (T)N3H···N7(A) (0.61 kcal·mol−1) H‐bonds, accordingly. Notably, in these two TSs amino group N6H2 of A is significantly pyramidilized; Gibbs free energies of activation for these reactions are 19.07 and 19.71 kcal·mol−1, accordingly.

show abstract

“…The effect of electric field on the chemical reactivity has been illustrated in several earlier studies [34][35][36][37][38][39][40][41][42][43][44]. Particularly, the chemical reactivity as a function of orientation in the electric field has been thoroughly investigated [34,35].…”

Section: Introductionmentioning

confidence: 99%

“…That the introduction of electric field influences both physical and chemical properties of various molecular systems are evident from these studies. Recently a number of works has been devoted to the study of application of external electric field on biological molecules [41][42][43][44].…”

Section: Introductionmentioning

confidence: 99%

Effect of external electric field on ground and singlet excited states of phenylalanine: A theoretical study

Bhattacharyya

2015

Computational and Theoretical Chemistry

View full text Add to dashboard Cite

Designing Molecular Switches Based on DNA-Base Mispairing

Cited by 55 publications

References 76 publications

Mesoscopic modeling of DNA denaturation rates: Sequence dependence and experimental comparison

Mesoscopic modeling of DNA denaturation rates: Sequence dependence and experimental comparison

Unexpected A·T(WC)↔A·T(rWC)/A·T(rH) and A·T(H)↔A·T(rH)/A·T(rWC) conformational transitions between the classical A·T DNA base pairs: A QM/QTAIM comprehensive study

Effect of external electric field on ground and singlet excited states of phenylalanine: A theoretical study

Contact Info

Product

Resources

About