Effect of DNA groove binder distamycin A upon chromatin structure

Distamycin A is a prototype minor groove binder, which binds to B-form DNA, preferentially at A/T rich sites. Extensive work in the past few decades has characterized the binding at the level of double stranded DNA. However, effect of the same on physiological DNA, i.e. DNA complexed in chromatin, h...

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Bibliographic Details
Published in:PloS one 2011-10, Vol.6 (10), p.e26486
Main Authors: Majumder, Parijat, Dasgupta, Dipak
Format: Article
Language:English
Subjects:
Animals
Antibiotics
Architecture
Binding
Biochemistry
Biology
Biophysics
Calorimetry
Cancer
Chromatin
Chromatin - chemistry
Compaction
Contraction
Deoxyribonucleic acid
Distamycin
Distamycins - chemistry
Distamycins - pharmacology
DNA
DNA - chemistry
DNA - metabolism
DNA structure
Electron microscopy
Enthalpy
Free energy
Interaction parameters
Ligands
Light scattering
Microscopy
Nuclear physics
Nucleic Acid Conformation
Nucleic Acid Synthesis Inhibitors
Parameter identification
Photon correlation spectroscopy
Physiological aspects
Physiological effects
Proteins
Rats
Rats, Sprague-Dawley
Specific heat
Studies
Thermodynamics
Titration
Titration calorimetry
Transmission electron microscopy
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Summary:Distamycin A is a prototype minor groove binder, which binds to B-form DNA, preferentially at A/T rich sites. Extensive work in the past few decades has characterized the binding at the level of double stranded DNA. However, effect of the same on physiological DNA, i.e. DNA complexed in chromatin, has not been well studied. Here we elucidate from a structural perspective, the interaction of distamycin with soluble chromatin, isolated from Sprague-Dawley rat. Chromatin is a hierarchical assemblage of DNA and protein. Therefore, in order to characterize the interaction of the same with distamycin, we have classified the system into various levels, according to the requirements of the method adopted, and the information to be obtained. Isothermal titration calorimetry has been employed to characterize the binding at the levels of chromatin, chromatosome and chromosomal DNA. Thermodynamic parameters obtained thereof, identify enthalpy as the driving force for the association, with comparable binding affinity and free energy for chromatin and chromosomal DNA. Reaction enthalpies at different temperatures were utilized to evaluate the change in specific heat capacity (ΔCp), which, in turn, indicated a possible binding associated structural change. Ligand induced structural alterations have been monitored by two complementary methods--dynamic light scattering, and transmission electron microscopy. They indicate compaction of chromatin. Using transmission electron microscopy, we have visualized the effect of distamycin upon chromatin architecture at di- and trinucleosome levels. Our results elucidate the simultaneous involvement of linker bending and internucleosomal angle contraction in compaction process induced by distamycin. We summarize here, for the first time, the thermodynamic parameters for the interaction of distamycin with soluble chromatin, and elucidate its effect on chromatin architecture. The study provides insight into a ligand induced compaction phenomenon, and suggests new mechanisms of chromatin architectural alteration.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0026486