Building the Interphase Nucleus: A study on the kinetics of 3D chromosome formation, temporal relation to active transcription, and the role of nuclear RNAs
Authors
Abramo, Kristin N.Faculty Advisor
Job DekkerAcademic Program
Interdisciplinary Graduate ProgramUMass Chan Affiliations
Program in Systems BiologyDocument Type
Doctoral DissertationPublication Date
2020-07-28Keywords
chromatinHi-C
transcription
RNA
telophase
kinetics
cell cycle
mitosis
interphase
chromosome conformation capture
CTCF
condensin
cohesin
TAD
topologically associated domain
loop extrusion
microphase separation
NCAPH
Rad21
NCAPH2
synchronization
G1 entry
triptolide
DRB
RNase A
Bioinformatics
Cell Biology
Computational Biology
Genomics
Laboratory and Basic Science Research
Molecular Biology
Molecular Genetics
Systems Biology
Metadata
Show full item recordAbstract
Following the discovery of the one-dimensional sequence of human DNA, much focus has been directed on microscopy and molecular techniques to learn about the spatial organization of chromatin in a 3D cell. The development of these powerful tools has enabled high-resolution, genome-wide analysis of chromosome structure under many different conditions. In this thesis, I focus on how the organization of interphase chromatin is established and maintained following mitosis. Mitotic chromosomes are folded into helical loop arrays creating short and condensed chromosomes, while interphase chromosomes are decondensed and folded into a number of structures at different length scales ranging from loops between CTCF sites, enhancers and promoters to topologically associating domains (TADs), and larger compartments. While the chromatin organization at these two very different states is well defined, the transition from a mitotic to interphase chromatin state is not well understood. The aim of this thesis is to determine how interphase chromatin is organized following mitotic chromosome decondensation and to interrogate factors potentially responsible for driving the transition. First, I determine the temporal order with which CTCF-loops, TADs, and compartments reform as cells exit mitosis, revealing a unique structure at the anaphase-telophase transition never observed before. Second, I test the role of transcription in reformation of 3D chromosome structure and show that active transcription is not required for the formation of most interphase chromatin features; instead, I propose that transcription relies on the proper formation of these structures. Finally, I show that RNA in the interphase nucleus can be degraded with only slight consequences on the overall chromatin organization, suggesting that once interphase chromatin structures are achieved, the structures are stable and RNA is only required to reduce the mixing of active and inactive compartments. Together, these studies further our understanding of how interphase structures form, how these structures relate to functional activities of the interphase cell, and the stability of chromatin structures over time.DOI
10.13028/a9gd-gw44Permanent Link to this Item
http://hdl.handle.net/20.500.14038/31325Rights
Licensed under a Creative Commons licenseDistribution License
http://creativecommons.org/licenses/by-nc/4.0/ae974a485f413a2113503eed53cd6c53
10.13028/a9gd-gw44
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