Understanding the molecular mechanisms behind regulation of chromatin folding through covalent modifications of the histone N-terminal tails is hampered by a lack of accessible chromatin containing precisely modified histones. We study the internal folding and intermolecular self-association of a chromatin system consisting of saturated 12-mer nucleosome arrays containing various combinations of completely acetylated lysines at positions 5, 8, 12 and 16 of histone H4, induced by the cations Na+, K+, Mg2+, Ca2+, cobalt-hexammine3+, spermidine3+ and spermine4+. Histones were prepared using a novel semi-synthetic approach with native chemical ligation. Acetylation of H4-K16, but not its glutamine mutation, drastically reduces cation-induced folding of the array. Neither acetylations nor mutations of all the sites K5, K8 and K12 can induce a similar degree of array unfolding. The ubiquitous K+, (as well as Rb+ and Cs+) showed an unfolding effect on unmodified arrays almost similar to that of H4-K16 acetylation. We propose that K+ (and Rb+/Cs+) binding to a site on the H2B histone (R96-L99) disrupts H4K16 ε-amino group binding to this specific site, thereby deranging H4 tail-mediated nucleosome–nucleosome stacking and that a similar mechanism operates in the case of H4-K16 acetylation. Inter-array self-association follows electrostatic behavior and is largely insensitive to the position or nature of the H4 tail charge modification.
All atom molecular dynamics simulations with explicit water were done to study the interaction between two parallel double-stranded DNA molecules in the presence of the multivalent counterions putrescine (2+), spermidine (3+), spermine (4+) and cobalt hexamine (3+). The inter-DNA interaction potential is obtained with the umbrella sampling technique. The attractive force is rationalized in terms of the formation of ion bridges, i.e., multivalent ions which are simultaneously bound to the two opposing DNA molecules. The lifetime of the ion bridges is short on the order of a few nanoseconds.
The interaction of DNA with the polyamine spermine 4ϩ (Spm 4ϩ ), sodium ions, and water molecules has been studied using molecular dynamics computer simulations in a system modeling a DNA crystal. The simulation model consisted of three B-DNA decamers in a periodic hexagonal cell, containing 1200 water molecules, 8 Spm 4ϩ , 32 Na ϩ , and 4 Cl Ϫ ions. The present paper gives a more detailed account of a recently published report of this system and compares results on this mixed Spm 4ϩ /Na ϩ -cation system with an molecular dynamics simulation carried out for the same DNA decamer under similar conditions with only sodium counterions (Korolev et al., 2001, J. Mol. Biol. 308:907). The presence of Spm 4ϩ makes significant influence on the DNA hydration and on the interaction of the sodium ions with DNA. Spermine pushes water molecules out of the minor groove, whereas Na ϩ attracts and organizes water around DNA. The major binding site of the Spm 4ϩ amino groups and the Na ϩ ions is the phosphate group of DNA. The flexible polyamine spermine displays a high presence in the minor groove but does not form long-lived and structurally defined complexes. Sodium ions compete with Spm 4ϩ for binding to the DNA bases in the minor groove. Sodium ions also have several strong binding sites in the major groove. The ability of water molecules, Spm 4ϩ , and Na ϩ to modulate the local structure of the DNA double helix is discussed.
Competitive binding of the most common cations of the cytoplasm (K(+), Na(+), Ca(2+), and Mg(2+)) with DNA was studied by equilibrating oriented DNA fibers with ethanol/water solutions (65 and 52% v/v EtOH) containing different combinations and concentrations of the counterions. The affinity of DNA for the cations decreases in the order Ca > Mg >> Na approximately K. The degree of Ca(2+) and/or Mg(2+) binding to DNA displays maximum changes just at physiological concentrations of salts (60-200 mM) and does not depend significantly on the ethanol concentration or on the kind of univalent cation (Na(+) or K(+)). Ca(2+) is more tightly bound to DNA and is replaced by the monovalent cations to a lesser extent than is Mg(2+). Similarly, Ca(2+) is a better competitor for binding to DNA than Mg(2+): the ion exchange equilibrium constant for a 1:1 mixture of Ca(2+) and Mg(2+) ions, K(c)(Ca)(Mg), changes from K(c)(Ca)(Mg) approximately 2 in 65% EtOH (in 3-30 mM NaCl and/or KCl) to K(c)(Ca)(Mg) approximately 1.2-1.4 in 52% EtOH (in 300 mM NaCl and/or KCl). DNA does not exhibit selectivity for Na(+) or K(+) in ethanol/water solutions either in the absence or in the presence of Ca(2+) and/or Mg(2+). The ion exchange experimental data are compared with results of grand canonical Monte Carlo (GCMC) simulations of systems of parallel and hexagonally ordered, uniformly and discretely charged polyions with the density and spatial distribution of the charged groups modeling B DNA. A quantitative agreement with experimental data on divalent-monovalent competition has been obtained for discretely charged models of the DNA polyion (for the uniformly charged cylinder model, coincidence with experiment is qualitative). The GCMC method gives also a qualitative description of experimental results for DNA binding competitions of counterions of the same charge (Ca(2+) with Mg(2+) or K(+) with Na(+)).
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.