UMD Theses and Dissertations
Permanent URI for this collectionhttp://hdl.handle.net/1903/3
New submissions to the thesis/dissertation collections are added automatically as they are received from the Graduate School. Currently, the Graduate School deposits all theses and dissertations from a given semester after the official graduation date. This means that there may be up to a 4 month delay in the appearance of a given thesis/dissertation in DRUM.
More information is available at Theses and Dissertations at University of Maryland Libraries.
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Item UNCOVERING THE BIOPHYSICAL MECHANISMS OF HISTONE COMPLEX ASSEMBLY(2018) Zhao, Haiqing; Papoian, Garegin A.; Biophysics (BIPH); Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)At the most basic level, inheritance in living beings occurs by passing the genomic information such as the DNA sequences from the parent generation to the offspring generation. Hence, it is a fundamental goal for every generation to efficiently express the genomic information and safely pass it on to the next generation. In human and other eukaryotic species, this mission is mediated via chromatin, a macromolecule with intricate hierarchical structure. The fundamental unit of chromatin is called a nucleosome, a complex of histone proteins wrapped around with DNA. To carry out diverse biological functions such as transcription and DNA replication, the DNA-protein complex must dynamically transition between more compact, closed states and more accessible, open ones. To fully understand the chromatin structure and dynamics, it is essential to comprehend the basic structural unit of chromatin, nucleosome. In this dissertation, I present my doctoral research in the exploration of the nucleosome dynamics problem, focusing on the assembly process of histone proteins. From histone monomer to dimer, then to tetramer, octamer, and nucleosome, I used different computational modeling theories and techniques, together with different experimental collaborations, to investigate the overall thermodynamics and specific mechanistic details of nucleosome dynamics at different levels. My work has shed light on the fundamental principles governing the histone protein folding and histone complex assembly, in particular, highlighting similarities and differences between the canonical and variant CENP-A histones.Item Molecular Dynamic Simulations of Nucleosomes and Histone Tails: The Effects of Histone Variance and Post-Translational Modification(2015) Winogradoff, David; Papoian, Garegin; Chemical Physics; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)The packaging of genomic information and the regulation of gene expression are both fundamentally important to eukaryotic life. Meters of human DNA must fit inside the micron-diameter nucleus while still rapidly becoming available for templated processes such as transcription, replication, and repair. Therefore, the DNA-protein complex known as chromatin must dynamically transition between more compact, closed states and more accessible, open ones. To fully understand chromatin structure and dynamics, it is necessary to employ a multifaceted approach, integrating different general philosophies and scientific techniques that include experiment and computation. Since the DNA in chromatin is organized into arrays of nucleosomes, we take a bottom-up approach in this dissertation, striving first to understand the structure and dynamics of an individual nucleosome and subdomains thereof. Atomistic computational methods have provided useful tools to study DNA and protein dynamics at the nanosecond, and recently microsecond, timescale. In this dissertation, we present recent developments in the understanding of the nucleosome though atomistic molecular dynamics (MD) simulations. By applying different all-atom MD computational techniques, we demonstrate that replacing the canonical H3 histone with the centromere-specific variant CENP-A translates to greater structural flexibility in the nucleosome, that replacing H3 with CENP-A increases the plasticity of an individual histone dimer, and that the effects of acetylation on the H4 histone tail are cumulative and specific to lysine 16 mono-acetylation.