Micromechanical Study of Hyperacetylated Nucleosomes Using Single Molecule Transverse Magnetic Tweezers

Nucleosomes are stable complexes of DNA and histone proteins that are essential for the proper functioning of the genome. These structures must be unwrapped and disassembled for processes such as gene expression, replication, and repair. Histone post-translational modifications (PTMs) are known to play a significant role in regulating the structural changes of nucleosomes. However, the underlying mechanisms by which these modifications function remain unclear. In this study, we report the results of single molecule micromanipulation experiments on DNA–protein complexes composed of hyperacetylated histone proteins using transverse magnetic tweezers. The experiments were conducted by pre-extending λ-DNA with a force less than 4 pN before introducing hyperacetylated histones into the sample chamber. The DNA shortened as the histones formed complexes with it and the nucleosome arrays were then exposed to increasing tension, resulting in quantized changes in the DNA’s extension with step sizes of (integral multiples of) ~50 nm. We also compared results of experiments using PTM histones and native histones with data collected for both types of histones for the same force ranges (2–80 pN) and loading rates. Our data show that hyperacetylated nucleosomes require an unbinding force of around ~2.5 pN, which is similar to that required for native histones. Moreover, we identified clear differences between the step-size distributions of native and hyperacetylated histones and found that in contrast to tethers reconstituted with native histones, the majority of nucleosomes in tethers compacted with hyperacetylated histones underwent disassembly at forces significantly lower than 6 pN.

[1]  A. Velázquez‐Campoy,et al.  Beyond a platform protein for the degradosome assembly: The Apoptosis-Inducing Factor as an efficient nuclease involved in chromatinolysis , 2022, PNAS nexus.

[2]  E. Verweij,et al.  BRET-Based Biosensors to Measure Agonist Efficacies in Histamine H1 Receptor-Mediated G Protein Activation, Signaling and Interactions with GRKs and β-Arrestins , 2022, International journal of molecular sciences.

[3]  M. Medina,et al.  Nanomechanical Study of Enzyme: Coenzyme Complexes: Bipartite Sites in Plastidic Ferredoxin-NADP+ Reductase for the Interaction with NADP+ , 2022, Antioxidants.

[4]  I. Pegg,et al.  Magnetic tweezers: development and use in single-molecule research. , 2022, BioTechniques.

[5]  M. Medina,et al.  Atomic Force Microscopy to Elicit Conformational Transitions of Ferredoxin-Dependent Flavin Thioredoxin Reductases , 2021, Antioxidants.

[6]  S. Minguzzi,et al.  Fluorescence Cross-Correlation Spectroscopy Yields True Affinity and Binding Kinetics of Plasmodium Lactate Transport Inhibitors , 2021, Pharmaceuticals.

[7]  I. Pegg,et al.  A Horizontal Magnetic Tweezers for Studying Single DNA Molecules and DNA-Binding Proteins , 2021, Molecules.

[8]  Nhuong V. Nguyen,et al.  Global profiling of protein–DNA and protein–nucleosome binding affinities using quantitative mass spectrometry , 2018, Nature Communications.

[9]  I. Pegg,et al.  A Horizontal Magnetic Tweezers and Its Use for Studying Single DNA Molecules , 2018, Micromachines.

[10]  W. Krajewski On the role of inter-nucleosomal interactions and intrinsic nucleosome dynamics in chromatin function , 2016, Biochemistry and biophysics reports.

[11]  P. Mehl,et al.  Simple horizontal magnetic tweezers for micromanipulation of single DNA molecules and DNA-protein complexes. , 2016, BioTechniques.

[12]  I Pegg,et al.  Automated nonparametric method for detection of step‐like features in biological data sets , 2015, Cytometry. Part A : the journal of the International Society for Analytical Cytology.

[13]  Michael G. Poirier,et al.  Post-Translational Modifications of Histones That Influence Nucleosome Dynamics , 2014, Chemical reviews.

[14]  B. Strahl,et al.  Interpreting the language of histone and DNA modifications. , 2014, Biochimica et biophysica acta.

[15]  Ralf Blossey,et al.  The dynamics of the nucleosome: thermal effects, external forces and ATP , 2011, The FEBS journal.

[16]  Robert A. Forties,et al.  Histone fold modifications control nucleosome unwrapping and disassembly , 2011, Proceedings of the National Academy of Sciences.

[17]  J. W. Picking,et al.  Acetylation of Histone H3 at the Nucleosome Dyad Alters DNA-Histone Binding* , 2009, The Journal of Biological Chemistry.

[18]  Ashby J. Morrison,et al.  Chromatin remodelling beyond transcription: the INO80 and SWR1 complexes , 2009, Nature Reviews Molecular Cell Biology.

[19]  Jeffrey G. Linger,et al.  Acetylated Lysine 56 on Histone H3 Drives Chromatin Assembly after Repair and Signals for the Completion of Repair , 2008, Cell.

[20]  D. Tuma,et al.  Microtubule acetylation and stability may explain alcohol‐induced alterations in hepatic protein trafficking , 2008, Hepatology.

[21]  Jie Yan,et al.  Nucleosome hopping and sliding kinetics determined from dynamics of single chromatin fibers in Xenopus egg extracts , 2007, Proceedings of the National Academy of Sciences.

[22]  M. Churchill,et al.  Structural Basis for the Histone Chaperone Activity of Asf1 , 2006, Cell.

[23]  Erica L. Mersfelder,et al.  The tale beyond the tail: histone core domain modifications and the regulation of chromatin structure , 2006, Nucleic acids research.

[24]  Jef D. Boeke,et al.  Insights into the Role of Histone H3 and Histone H4 Core Modifiable Residues in Saccharomyces cerevisiae , 2005, Molecular and Cellular Biology.

[25]  M. Grunstein,et al.  Acetylation in Histone H3 Globular Domain Regulates Gene Expression in Yeast , 2005, Cell.

[26]  Jef D Boeke,et al.  Regulated nucleosome mobility and the histone code , 2004, Nature Structural &Molecular Biology.

[27]  Jie Yan,et al.  Near-field-magnetic-tweezer manipulation of single DNA molecules. , 2004, Physical review. E, Statistical, nonlinear, and soft matter physics.

[28]  Karolin Luger,et al.  Crystal structures of histone Sin mutant nucleosomes reveal altered protein–DNA interactions , 2004, The EMBO journal.

[29]  Andrew Flaus,et al.  Sin mutations alter inherent nucleosome mobility , 2004, The EMBO journal.

[30]  Michael A. Freitas,et al.  Identification of novel histone post-translational modifications by peptide mass fingerprinting , 2003, Chromosoma.

[31]  Uma M. Muthurajan,et al.  Structure and dynamics of nucleosomal DNA. , 2003, Biopolymers.

[32]  Michelle D. Wang,et al.  Mechanical disruption of individual nucleosomes reveals a reversible multistage release of DNA , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[33]  J. Hansen,et al.  Conformational dynamics of the chromatin fiber in solution: determinants, mechanisms, and functions. , 2002, Annual review of biophysics and biomolecular structure.

[34]  C. Allis,et al.  Translating the Histone Code , 2001, Science.

[35]  C. Allis,et al.  The language of covalent histone modifications , 2000, Nature.

[36]  Alan P. Wolffe,et al.  Disruption of Higher-Order Folding by Core Histone Acetylation Dramatically Enhances Transcription of Nucleosomal Arrays by RNA Polymerase III , 1998, Molecular and Cellular Biology.

[37]  A. Wolffe,et al.  Sin mutations of histone H3: influence on nucleosome core structure and function , 1997, Molecular and cellular biology.

[38]  T. Richmond,et al.  Crystal structure of the nucleosome core particle at 2.8 Å resolution , 1997, Nature.

[39]  S. Smith,et al.  Direct mechanical measurements of the elasticity of single DNA molecules by using magnetic beads. , 1992, Science.

[40]  R. Simpson Structure of chromatin containing extensively acetylated H3 and H4 , 1978, Cell.

[41]  R. Kornberg Chromatin structure: a repeating unit of histones and DNA. , 1974, Science.