dna unwrapping
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2022 ◽  
Author(s):  
Jiayi Fan ◽  
Andrew T Moreno ◽  
Alexander S Baier ◽  
Joseph J Loparo ◽  
Craig L Peterson

The histone variant H2A.Z is a conserved feature of nucleosomes flanking protein-coding genes. Deposition of H2A.Z requires ATP-dependent replacement of nucleosomal H2A by a chromatin remodeler related to the multi-subunit enzyme, yeast SWR1C. How these enzymes use ATP to promote this nucleosome editing reaction remains unclear. Here we use single-molecule and ensemble methodologies to identify three ATP-dependent phases in the H2A.Z deposition reaction. Real-time analysis of single nucleosome remodeling events reveals an initial, priming step that occurs after ATP addition that likely involves transient DNA unwrapping from the nucleosome. Priming is followed by rapid loss of histone H2A, which is subsequently released from the H2A.Z nucleosomal product. Surprisingly, the rates of both priming and the release of the H2A/H2B dimer are sensitive to ATP concentration. This complex reaction pathway provides multiple opportunities to regulate the timely and accurate deposition of H2A.Z at key genomic locations.


2021 ◽  
Vol 11 (1) ◽  
Author(s):  
Tommy Stormberg ◽  
Sridhar Vemulapalli ◽  
Shaun Filliaux ◽  
Yuri L. Lyubchenko

AbstractChromatin structure is dictated by nucleosome assembly and internucleosomal interactions. The tight wrapping of nucleosomes inhibits gene expression, but modifications to histone tails modulate chromatin structure, allowing for proper genetic function. The histone H4 tail is thought to play a large role in regulating chromatin structure. Here we investigated the structure of nucleosomes assembled with a tail-truncated H4 histone using Atomic Force Microscopy. We assembled tail-truncated H4 nucleosomes on DNA templates allowing for the assembly of mononucleosomes or dinucleosomes. Mononucleosomes assembled on nonspecific DNA led to decreased DNA wrapping efficiency. This effect is less pronounced for nucleosomes assembled on positioning motifs. Dinucleosome studies resulted in the discovery of two effects- truncation of the H4 tail does not diminish the preferential positioning observed in full-length nucleosomes, and internucleosomal interaction eliminates the DNA unwrapping effect. These findings provide insight on the role of histone H4 in chromatin structure and stability.


2021 ◽  
Author(s):  
Shuxiang Li ◽  
Yunhui Peng ◽  
David Landsman ◽  
Anna Panchenko

Cytosine methylation at the 5-carbon position is an essential DNA epigenetic mark in many eukaryotic organisms. Although countless structural and functional studies of cytosine methylation have been reported in both prokaryotes and eukaryotes, our understanding of how it influences the nucleosome assembly, structure, and dynamics remains obscure. Here we investigated the effects of cytosine methylation at CpG sites on nucleosome dynamics and stability. By applying long molecular dynamics simulations (five microsecond long trajectories, 60 microseconds in total), we generated extensive atomic level conformational full nucleosome ensembles. Our results revealed that methylation induces pronounced changes in geometry for both linker and nucleosomal DNA, leading to a more curved, under-twisted DNA, shifting the population equilibrium of sugar-phosphate backbone geometry. These conformational changes are associated with a considerable enhancement of interactions between methylated DNA and the histone octamer, doubling the number of contacts at some key arginines. H2A and H3 tails play important roles in these interactions, especially for DNA methylated nucleosomes. This, in turn, prevents a spontaneous DNA unwrapping of 3-4 helical turns for the methylated nucleosome with truncated histone tails, otherwise observed in the unmethylated system on several microsecond time scale.


2021 ◽  
Vol 12 (1) ◽  
Author(s):  
Grigoriy A. Armeev ◽  
Anastasiia S. Kniazeva ◽  
Galina A. Komarova ◽  
Mikhail P. Kirpichnikov ◽  
Alexey K. Shaytan

AbstractNucleosomes are elementary building blocks of chromatin in eukaryotes. They tightly wrap ∼147 DNA base pairs around an octamer of histone proteins. How nucleosome structural dynamics affect genome functioning is not completely clear. Here we report all-atom molecular dynamics simulations of nucleosome core particles at a timescale of 15 microseconds. At this timescale, functional modes of nucleosome dynamics such as spontaneous nucleosomal DNA breathing, unwrapping, twisting, and sliding were observed. We identified atomistic mechanisms of these processes by analyzing the accompanying structural rearrangements of the histone octamer and histone-DNA contacts. Octamer dynamics and plasticity were found to enable DNA unwrapping and sliding. Through multi-scale modeling, we showed that nucleosomal DNA dynamics contribute to significant conformational variability of the chromatin fiber at the supranucleosomal level. Our study further supports mechanistic coupling between fine details of histone dynamics and chromatin functioning, provides a framework for understanding the effects of various chromatin modifications.


2021 ◽  
Author(s):  
Grigoriy A. Armeev ◽  
Anastasia S. Kniazeva ◽  
Galina A. Komarova ◽  
Mikhail P. Kirpichnikov ◽  
Alexey K. Shaytan

AbstractNucleosomes are elementary building blocks of chromatin in eukaryotes. They tightly wrap ~147 DNA base pairs around an octamer of histone proteins. How nucleosome structural dynamics affect genome functioning is not completely clear. Here we report all-atom molecular dynamics simulations of nucleosome core particles at a timescale of 15 microseconds. At this timescale, functional modes of nucleosome dynamics such as spontaneous nucleosomal DNA breathing, unwrapping, twisting, and sliding were observed. We identified atomistic mechanisms of these processes by analyzing the accompanying structural rearrangements of the histone octamer and histone-DNA contacts. Octamer dynamics and plasticity were found to enable DNA unwrapping and sliding. Through multi-scale modeling, we showed that nucle-osomal DNA dynamics contribute to significant conformational variability of the chromatin fiber at the supranucleosomal level. Our study further supports mechanistic coupling between fine details of histone dynamics and chromatin functioning, provides a framework for understanding the effects of various chromatin modifications.We developed a web site for an interactive preview of molecular dynamics trajectories at https://intbio.github.io/Armeev_et_al_2021.


2021 ◽  
Author(s):  
Yihang Jing ◽  
Gaofei Tian ◽  
Xiaoyu Qin ◽  
Zheng Liu ◽  
Xiang David Li

Lysine succinylation (Ksucc) is a novel posttranslational modification that frequently occurs on chromatin proteins including histones and non-histone proteins. Histone Ksucc affects nucleosome dynamics by increasing DNA unwrapping rate and...


PLoS ONE ◽  
2019 ◽  
Vol 14 (3) ◽  
pp. e0212764 ◽  
Author(s):  
Randi M. Mackler ◽  
Nathan D. Jones ◽  
Anne M. Gardner ◽  
Miguel A. Lopez ◽  
Cecil J. Howard ◽  
...  

Science ◽  
2018 ◽  
Vol 362 (6411) ◽  
pp. 194.11-196
Author(s):  
Steve Mao

2018 ◽  
Vol 115 (5) ◽  
pp. 773-781 ◽  
Author(s):  
Alexander W. Mauney ◽  
Joshua M. Tokuda ◽  
Lisa M. Gloss ◽  
Oscar Gonzalez ◽  
Lois Pollack

2018 ◽  
Author(s):  
Jaewon Kirk ◽  
Ju Yeon Lee ◽  
Yejin Lee ◽  
Chanshin Kang ◽  
Soochul Shin ◽  
...  

AbstractChromodomain-helicase-DNA-binding protein 1 (CHD1) remodels chromatin by translocating nucleosomes along DNA, but its mechanism remains poorly understood. Here, we employ a single-molecule fluorescence approach to characterize nucleosome remodeling by yeast CHD1 (Chd1p). We show that Chd1p translocates nucleosomes in steps of multiple base pairs per ATP. ATP binding to Chd1p induces a transient unwrapping of the exit-side DNA, and facilitates nucleosome translocation. ATP hydrolysis induces nucleosome translocation, which is followed by the rewrapping upon the release of the hydrolyzed nucleotide. Multiple Chd1ps binding to a single nucleosome sequentially moves a histone octamer with a preference to the center of DNA fragments, suggesting a new mechanism for regularly spaced nucleosome generation by Chd1p. Our results reveal the unique mechanism by which Chd1p remodels nucleosomes.Significance StatementThere are four major ATP-dependent chromatin remodeler families: SWI/SNF, ISWI, CHD, and INO80/SWR1. The remodeling mechanisms of SWI/SNF and ISWI chromatin remodelers have been elucidated through extensive single-molecule studies, but it remains poorly understood how CHD chromatin remodeler operate. We use single-molecule FRET techniques, and show that Yeast CHD1 uses unique mechanisms to remodel a nucleosome.


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