Indirect readout in drug-DNA recognition: role of sequence-dependent DNA conformation

Abstract We present a multi-laboratory effort to describe the structural and dynamical properties of duplex B-DNA under physiological conditions. By processing a large amount of atomistic molecular dynamics simulations, we determine the sequence-dependent structural properties of DNA as expressed in the equilibrium distribution of its stochastic dynamics. Our analysis includes a study of first and second moments of the equilibrium distribution, which can be accurately captured by a harmonic model, but with nonlocal sequence-dependence. We characterize the sequence-dependent choreography of backbone and base movements modulating the non-Gaussian or anharmonic effects manifested in the higher moments of the dynamics of the duplex when sampling the equilibrium distribution. Contrary to prior assumptions, such anharmonic deformations are not rare in DNA and can play a significant role in determining DNA conformation within complexes. Polymorphisms in helical geometries are particularly prevalent for certain tetranucleotide sequence contexts and are always coupled to a complex network of coordinated changes in the backbone. The analysis of our simulations, which contain instances of all tetranucleotide sequences, allow us to extend Calladine–Dickerson rules used for decades to interpret the average geometry of DNA, leading to a set of rules with quantitative predictive power that encompass nonlocal sequence-dependence and anharmonic fluctuations.

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The Role of Sequence-Dependent Mechanics in DNA Looping

Biophysical Journal ◽

10.1016/j.bpj.2008.12.1005 ◽

2009 ◽

Vol 96 (3) ◽

pp. 20a

Author(s):

David P. Wilson ◽

J.C. Meiners ◽

Todd Lillian ◽

Alexei Tkachenko ◽

Noel C. Perkins

Keyword(s):

Dna Looping ◽

Sequence Dependent

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Reprogrammable Recognition Codes in Bicoid Homeodomain-DNA Interaction

Molecular and Cellular Biology ◽

10.1128/mcb.20.20.7673-7684.2000 ◽

2000 ◽

Vol 20 (20) ◽

pp. 7673-7684 ◽

Cited By ~ 32

Author(s):

Vrushank Dave ◽

Chen Zhao ◽

Fan Yang ◽

Chang-Shung Tung ◽

Jun Ma

Keyword(s):

Dna Sequences ◽

Human Disease ◽

Dna Recognition ◽

Dna Interaction ◽

Morphogenetic Protein ◽

Different Types ◽

Disease Protein

ABSTRACT We describe experiments to determine how the homeodomain of the Drosophila morphogenetic protein Bicoid recognizes different types of DNA sequences found in natural enhancers. Our chemical footprint analyses reveal that the Bicoid homeodomain makes both shared and distinct contacts with a consensus site A1 (TAATCC) and a nonconsensus site X1 (TAAGCT). In particular, the guanine of X1 at position 4 (TAAGCT) is protected by Bicoid homeodomain. We provide further evidence suggesting that the unique arginine at position 54 (Arg 54) of the Bicoid homeodomain enables the protein to recognize X1 by specifically interacting with this position 4 guanine. We also describe experiments to analyze the contribution of artificially introduced Arg 54 to DNA recognition by other Bicoid-related homeodomains, including that from the human disease protein Pitx2. Our experiments demonstrate that the role of Arg 54 varies depending on the exact homeodomain framework and DNA sequences. Together, our results suggest that Bicoid and its related homeodomains utilize distinct recognition codes to interact with different DNA sequences, underscoring the need to study DNA recognition by Bicoid-class homeodomains in an individualized manner.

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The role of technical information in scheduling problems with sequence dependent setup times

Procedia Manufacturing ◽

10.1016/j.promfg.2020.10.210 ◽

2020 ◽

Vol 51 ◽

pp. 1508-1514

Author(s):

A. Grieco ◽

P. Caricato ◽

D. Gianfreda ◽

A. Pierpaoli

Keyword(s):

Technical Information ◽

Setup Times ◽

Scheduling Problems ◽

Sequence Dependent ◽

Sequence Dependent Setup ◽

Dependent Setup Times ◽

Sequence Dependent Setup Times

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Structure-guided DNA–DNA attraction mediated by divalent cations

Nucleic Acids Research ◽

10.1093/nar/gkaa499 ◽

2020 ◽

Author(s):

Amit Srivastava ◽

Raju Timsina ◽

Seung Heo ◽

Sajeewa W Dewage ◽

Serdal Kirmizialtin ◽

...

Keyword(s):

Electrostatic Interactions ◽

Alkaline Earth ◽

Divalent Cations ◽

Random Sequence ◽

Earth Metal ◽

Alkaline Earth Metal ◽

Sequence Dependent ◽

Phosphate Backbone ◽

Alkaline Earth Metal Ions

Abstract Probing the role of surface structure in electrostatic interactions, we report the first observation of sequence-dependent dsDNA condensation by divalent alkaline earth metal cations. Disparate behaviors were found between two repeating sequences with 100% AT content, a poly(A)-poly(T) duplex (AA-TT) and a poly(AT)-poly(TA) duplex (AT-TA). While AT-TA exhibits non-distinguishable behaviors from random-sequence genomic DNA, AA-TT condenses in all alkaline earth metal ions. We characterized these interactions experimentally and investigated the underlying principles using computer simulations. Both experiments and simulations demonstrate that AA-TT condensation is driven by non-specific ion–DNA interactions. Detailed analyses reveal sequence-enhanced major groove binding (SEGB) of point-charged alkali ions as the major difference between AA-TT and AT-TA, which originates from the continuous and close stacking of nucleobase partial charges. These SEGB cations elicit attraction via spatial juxtaposition with the phosphate backbone of neighboring helices, resulting in an azimuthal angular shift between apposing helices. Our study thus presents a distinct mechanism in which, sequence-directed surface motifs act with cations non-specifically to enact sequence-dependent behaviors. This physical insight allows a renewed understanding of the role of repeating sequences in genome organization and regulation and offers a facile approach for DNA technology to control the assembly process of nanostructures.

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