CD of the li‐salt of DNA in ethanol/water mixtures: Evidence for the B‐ to C‐form transition in solution

Bokma, J.T.; Curtis, W. Johnson; Blök, J.

doi:10.1002/bip.360260609

Cited by 59 publications

(43 citation statements)

References 56 publications

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“…29 However, in this case the negative peak at 245 nm does not change in intensity, as it did when polyaniline is present. Additional changes in the 245 nm band of the DNApolyaniline complex indicate a transition similar to what is observed for a "B" to "C" polymorph transition 38 and is perhaps evidence of a new type of DNA polymorph. This significant conformational change in DNA induced by the polymerization of aniline supports the formation of a charged, emeraldine salt form of polyaniline that is complexed to the DNA template.…”

Section: Resultssupporting

confidence: 66%

“…These changes are indicative of the polymorphic transition in DNA from a loosely wound "B" form (containing 10.4 base pairs per turn) to the over-wound form (containing less than 10 base pairs per turn). 27 The formation of polyaniline on the DNA template is concomitant with the shielding of charges on the phosphate groups of the DNA. This shielding of charge on the phosphate groups by the polyaniline reduces the electrostatic repulsion between successive phosphate groups, leading to the formation of the over-wound polymorph.…”

Section: Resultsmentioning

confidence: 99%

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Manipulating DNA Conformation Using Intertwined Conducting Polymer Chains

Nagarajan¹,

Liu²,

Kumar³

et al. 2001

Macromolecules

149

124

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In the field of inherently conducting polymers, polyaniline (Pani) has elicited tremendous interest due to its promising electrical properties and unique redox tunability. Synthetic routes involving the use of polyelectrolytes have significantly improved the processability of polyaniline. Recently, a template guided synthesis catalyzed by an enzyme, horseradish peroxidase (HRP), has provided a means of polymerizing aniline under milder pH conditions (pH 4.3) and subsequently widened the choice of templates to more delicate biological macromolecules. Here we report a strategy that exploits the inherent molecular order as well as the polyelectrolyte behavior of DNA to enzymatically synthesize and biologically assemble conducting polyaniline. This "wrapping" of polyaniline on DNA has been found to induce reversible changes in the secondary structure of DNA, leading to the formation of an over-wound polymorph. The polyaniline synthesized on the DNA also exhibited a template-induced macroasymmetry. This unique polyaniline/DNA intertwined complex has been used to "probe" and control the conformation of the DNA double helix.

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Section: Resultssupporting

confidence: 66%

Section: Resultsmentioning

confidence: 99%

Manipulating DNA Conformation Using Intertwined Conducting Polymer Chains

Nagarajan¹,

Liu²,

Kumar³

et al. 2001

Macromolecules

149

124

View full text Add to dashboard Cite

show abstract

“…Soon after its publication, the P-DNA structure appeared to be untenable in the light of the Watson-Crick model (28) for DNA under physiological conditions. Subsequently, some evidence existed to assume the presence of double-stranded P-DNA, but only under very particular conditions in dry DNA (29) or ethanol solutions (30) (see also ref. 31).…”

mentioning

confidence: 99%

On structural transitions, thermodynamic equilibrium, and the phase diagram of DNA and RNA duplexes under torque and tension

Wereszczynski

Andricioaei

2006

Proc. Natl. Acad. Sci. U.S.A.

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A precise understanding of the flexibility of double stranded nucleic acids and the nature of their deformed conformations induced by external forces is important for a wide range of biological processes including transcriptional regulation, supercoil and catenane removal, and site-specific recombination. We present, at atomic resolution, a simulation of the dynamics involved in the transitions from B-DNA and A-RNA to Pauling (P) forms and to denatured states driven by application of external torque and tension. We then calculate the free energy profile along a B-to P-transition coordinate and from it, compute a reversible pathway, i.e., an isotherm of tension and torque pairs required to maintain P-DNA in equilibrium. The reversible isotherm maps correctly onto a phase diagram derived from single molecule experiments, and yields values of elongation, twist, and twist-stretch coupling in agreement with measured values. We also show that configurational entropy compensates significantly for the large electrostatic energy increase due to closer-packed P backbones. A similar set of simulations applied to RNA are used to predict a novel structure, P-RNA, with its associated free energy, equilibrium tension, torque and structural parameters, and to assign the location, on the phase-diagram,

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“…Subsequently, alteration in these native properties of B-DNA (winding angle and propeller twist) causes small change in number of base pairs per turn in DNA duplex (Patil & Rhodes, 2000;Portugal & Subirana, 1985). Therefore, altogether, these spectral alterations make a prospect for the transition of native DNA conformation from B-form (10.4 base pair/helical turn) to C-form (9.2 base pair/helical turn) (Bokma, Curtis, & Blok, 1987;Portugal & Subirana, 1985;Zhang, Huang, Tang, Wang, & Dong, 2002). However, this transition appears to be limited up to few base pairs of DNA as for the complete transformation from B-to C-form, ellipticity at 248 nm must be in the exact ratio of two-third (66%) to that of B-DNA band, while here, we observed 70% intensification (Bokma et al, 1987;Brahms, Pilet, Lan, & Hill, 1973;Portugal & Subirana, 1985).…”

Section: Spectroscopic Analysismentioning

confidence: 99%

Molecular modeling and spectroscopic studies of semustine binding with DNA and its comparison with lomustine–DNA adduct formation

Agarwal¹,

Chadha²,

Mehrotra³

2014

Journal of Biomolecular Structure and Dynamics

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Chloroethyl nitrosoureas constitute an important family of cancer chemotherapeutic agents, used in the treatment of various types of cancer. They exert antitumor activity by inducing DNA interstrand cross-links. Semustine, a chloroethyl nitrosourea, is a 4-methyl derivative of lomustine. There exist some interesting reports dealing with DNA-binding properties of chloroethyl nitrosoureas; however, underlying mechanism of cytotoxicity caused by semustine has not been precisely and completely delineated. The present work focuses on understanding semustine-DNA interaction to comprehend its anti-proliferative action at molecular level using various spectroscopic techniques. Attenuated total reflection-Fourier transform infrared (ATR-FTIR) spectroscopy is used to determine the binding site of semustine on DNA. Conformational transition in DNA after semustine complexation is investigated using circular dichroism (CD) spectroscopy. Stability of semustine-DNA complexes is determined using absorption spectroscopy. Results of the present study demonstrate that semustine performs major-groove-directed DNA alkylation at guanine residues in an incubation-time-drug-concentration-dependent manner. CD spectral outcomes suggest partial transition of DNA from native B-conformation to C-form. Calculated binding constants (K a ) for semustine and lomustine interactions with DNA are 1.53 × 10 3 M −1 and 8.12 × 10 3 M −1 , respectively. Moreover, molecular modeling simulation is performed to predict preferential binding orientation of semustine with DNA that corroborates well with spectral outcomes. Results based on comparative study of DNA-binding properties of semustine and lomustine, presented here, may establish a correlation between molecular structure and cytotoxicity of chloroethyl nitrosoureas that may be instrumental in the designing and synthesis of new nitrosourea therapeutics possessing better efficacy and fewer side effects.

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CD of the li‐salt of DNA in ethanol/water mixtures: Evidence for the B‐ to C‐form transition in solution

Cited by 59 publications

References 56 publications

Manipulating DNA Conformation Using Intertwined Conducting Polymer Chains

Manipulating DNA Conformation Using Intertwined Conducting Polymer Chains

On structural transitions, thermodynamic equilibrium, and the phase diagram of DNA and RNA duplexes under torque and tension

Molecular modeling and spectroscopic studies of semustine binding with DNA and its comparison with lomustine–DNA adduct formation

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