Your search keyword '"DNA, A-Form"' showing total 3 results

1. Transformation characteristics of A-DNA in salt solution revealed through molecular dynamics simulations

Author

Jingjing Xue, Peng Wang, Xinpeng Li, Rongri Tan, and Wenjun Zong

Subjects

Cations, Organic Chemistry, Biophysics, DNA, DNA, A-Form, Molecular Dynamics Simulation, Sodium Chloride, Biochemistry

Abstract

The structure of A-DNA with biological activity is double helix. Researches of A-DNA structure have wide application on the development of DNA drug. In aqueous solution, the structure of A-DNA will have a free transformation over time and be finally stabilized in the B-form. In this work, molecular dynamics simulations have been performed on the A-DNA with sequence of CCCGGCCGGG, to elucidate the influence of ionic valence and temperature on the structural stability of A-DNA in salt solution. The results show that the structure of A-DNA is more stable in AlCl

Published

2022

2. Transformation characteristics of A-DNA in salt solution revealed through molecular dynamics simulations.

Author

Xue J, Wang P, Li X, Tan R, and Zong W

Subjects

Cations, DNA chemistry, Sodium Chloride, DNA, A-Form, Molecular Dynamics Simulation

Abstract

The structure of A-DNA with biological activity is double helix. Researches of A-DNA structure have wide application on the development of DNA drug. In aqueous solution, the structure of A-DNA will have a free transformation over time and be finally stabilized in the B-form. In this work, molecular dynamics simulations have been performed on the A-DNA with sequence of CCCGGCCGGG, to elucidate the influence of ionic valence and temperature on the structural stability of A-DNA in salt solution. The results show that the structure of A-DNA is more stable in AlCl 3 solution compared with MgCl 2 and NaCl solution. To further discuss the influence of ionic valency, two kinds of virtual ions (monovalent X + and trivalent Z 3+ ) are created based on the properties of magnesium ions. From the simulations, the stability of A-DNA structure is better in high valent cationic salt solution. This has something to do with electrostatic interaction between metal ions and DNA chains. The electrostatic interaction force is gradually improved with the increasing of ionic valency, which is conducive to the formation of more compact DNA structure. Also, in the condition of same concentration and ionc valency, low temperature has a contribution to the stability of A-DNA structure., (Copyright © 2022 Elsevier B.V. All rights reserved.)

Published

2022

3. Photochemical probing of the B--a conformational transition in a linearized pUC19 DNA and its polylinker region

Author

Jana Chládková, Jaroslav Kypr, and Karel Nejedlý

Subjects

Stereochemistry, Photochemistry, Ultraviolet Rays, Molecular Sequence Data, Biophysics, EcoRI, Pyrimidine dimer, DNA, A-Form, Cleavage (embryo), Biochemistry, Primer extension, chemistry.chemical_compound, Nucleotide, chemistry.chemical_classification, biology, Base Sequence, Chemistry, Circular Dichroism, Organic Chemistry, DNA, DNA Restriction Enzymes, Molecular biology, Restriction enzyme, biology.protein, Nucleic Acid Conformation, Cytosine, Plasmids

Abstract

We induced the B-to-A conformational transition by ethanol in a linearized pUC19 DNA. A primer extension method was used in combination with UV light irradiation to follow the transition, based on pausing of DNA synthesis due to the presence of damaged bases in the template. Primer extension data highly correlated with the results of another method monitoring the B–A transition, i.e. inhibition of restriction endonuclease cleavage of UV light-irradiated DNA. Primer extension enabled us to locate damaged nucleotides within the region of interest. Most damaged nucleotides were located in B-form trimers, exclusively containing both pyrimidine bases (TTC, TCT, CTC, and CTT), and in a cytosine tetramer. The amount of damaged bases decreased in the course of B–A transition. Some of the damage even disappeared in the A-form, which mainly concerns the C 4 and C 3 blocks. The cleavage was nearly restored in the A-form within this region ( Eco 88I). On the contrary the decrease of damage was less significant with thymine dimers, only dropping to 50–60% of the B-form level. Consequently, the cleavage with Eco RI and Hind III remained mostly as before the transition (75% and 60% of uncleaved DNA preserved). We found significant differences in the B- and A-form pattern of UV light-damaged bases within the same region (polylinker) of DNA embedded within long (plasmid) or short (127 bp fragment) DNA molecules. The B–A transition of the fragment was found less cooperative than with linearized plasmid, which was confirmed by both CD spectroscopy and restriction cleavage inhibition.

Published

2006