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How Chromosome-Nuclear Envelope Attachments Affect 3D Genome OrganizationKinney, Nicholas A. 04 April 2016 (has links)
The length of eukaryotic chromosomes is many times longer than the nucleus diameter in most cells; thus, their confinement depends on adopting highly folded configurations. Remarkably, these configurations are non-random and may be important for gene expression and regulation. Thus, genome sequences must be understood in the context of their 3D organization which critically influences the flow of information. The effort to understand this added complexity now encompasses an entire field of chromosome biology and is reshaping the traditional concept of the central dogma. Although little is known about the principles which govern chromosome folding and influence gene regulation, the nuclear envelope is expected to play a significant role since it serves as the physical boundary preventing chromosome from freely diffusing in the cell cytosol. Moreover, experiments suggest that the nuclear envelope engages chromosomes actively by anchoring specific loci and limiting their range of motion. The broad goal of the research presented in this dissertation is to advance our understanding of 3D genome organization with an emphasis on determining the role of the nuclear envelope. / Ph. D.
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Biology at single-molecule and single-cell level: chromosome organization, gene expression and beyondChen, Chongyi January 2014 (has links)
Single molecules and single cells are the fundamental building blocks in biology. Facilitated by the advancement of technology, quantitative single-molecule and single-cell measurements provide a unique perspective toward many biological systems by revealing individual stochasticity and population heterogeneity. Taking advantage of these approaches, we studied chromosome organization and gene expression in bacteria and discovered new biophysical mechanisms: chromosome organization by a nucleoid-associated protein in live bacteria, and transcriptional bursting by the regulation of DNA supercoiling in bacteria.
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STRUCTURAL INSIGHTS INTO THE ROLES OF SEQA ON ORIGIN SEQUESTRATION AND CHROMOSOME ORGANIZATIONChung, Yu Seon 10 1900 (has links)
<p>DNA replication is a fundamental process that must be precisely regulated to ensure timely and faithful transmission of genetic material for proliferation of all organisms. Replication initiation is regulated through a series of precisely timed protein–DNA and protein–protein interactions. In <em>Escherichia coli</em>, one regulatory mechanism of replication initiation occurs through SeqA binding to specific sequences within the <em>oriC</em>, resulting in origin sequestration. SeqA also plays a role in chromosome organization at the replication forks. Despite the functional importance of SeqA in <em>E. coli</em>, its DNA binding mechanism has remained elusive. The work described in this thesis has shown for the first time the minimal functional unit of SeqA that forms a high-affinity complex with DNA through the loss of symmetry. This is a novel observation that explains how SeqA can distinguish template versus newly replicated strand of DNA. We have also identified a protein–protein interaction surface that separates the roles of SeqA at the origin in sequestration and at the replication forks in chromosome organization. The final contribution of the thesis is in the exploration of SeqA functions in other bacterial species and demonstrating the structural and functional similarities between <em>Vibrio cholerae </em>SeqA and <em>E. coli </em>SeqA. Together our work has made a crucial connection between the structural organization of the protein and its functional ability to bind DNA.</p> / Doctor of Philosophy (PhD)
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L'organisation 3D des chromosomes synthétiques de levure / 3D organisation of synthetic yeast chromosomesMercy, Guillaume 29 January 2018 (has links)
Le projet international de synthèse des chromosomes de S. cerevisiae (projet Sc2.0) a débuté il y a une dizaine d'années en suivant des principes établis par le Pr. Jef Boeke. Les chromosomes synthétiques ont été conçus pour augmenter la stabilité du génome en supprimant toutes les séquences répétées (ARNt, éléments transposables...), tout en y ajoutant un système d'évolution inductible dépendant du système Cré/LoxP (système SCRaMbLE), permettant de générer rapidement des réarrangements chromosomiques. Bien que le design du projet Sc2.0 soit très conservateur en ce qui concerne le contenu des gènes, la suppression de plusieurs classes de séquences répétées peut affecter l'organisation du génome et potentiellement altérer les fonctions cellulaires. En utilisant la méthode de capture de conformation de chromosome couplée au séquençage de seconde génération (Hi-C), mon objectif a été de caractériser l'organisation 3D des génomes des souches synthétiques et évoluées. À ce jour, huit chromosomes (syn I, II, III, V, VI, IX-R, X et XII) ont été entièrement assemblés séparément. En utilisant les souches contenant un ou plusieurs de ces chromosomes, nous avons pu montrer que leur organisation génomique n'est globalement pas affectée par leur présence. Quelques exceptions subsistent, avec synIII dont les cassettes HML et HMR ont été retirées, et synXII d'où l'ADNr a été déplacé sur un autre chromosome. À ce stade, nous concluons que l'ADN répétitif dispersé ne conduit pas la conformation moyenne globale du génome de S. cerevisiae. Nous avons aussi exploité les cartes de contacts pour identifier les réarrangements dans les souches SCRaMbLE. / The international project Sc2.0 started 10 years ago by the Pr. Jef Boeke aims to build a fully synthetic genome of S. cerevisiae which increases the genome stability by removing all repeated sequences (tRNA, transposable elements, etc.), and implements SCRaMbLE (for Synthetic Chromosome Rearrangement and Modification by LoxP-mediated Evolution), an inducible, high-throughput chromosome rearrangement system. This design is highly conservative with respect to gene content, the deletion of several classes of repeated sequences and the introduction of thousands of designer changes. However, it may affect genome organization and potentially alter cellular functions. To determine wether those modifications affected the three-dimensional conformation of synthetic chromosmes, we investigated it using chromosomes conformation capture coupled to second generation sequencing method (Hi-C). Currently, eight synthetic chromosomes (synI, synII, synIII, synV, synVI, synIX-R, synX et synXII) have been fully assembled. Using these strains we observed that the large-scale genomic organization is globally unaffected by the presence of synthetic chromosome(s). Two exceptions are synIII, which lacks the silent mating-type cassettes, and synXII, specifically when the ribosomal DNA is moved to another chromosome. We also exploited the contact maps to detect rearrangements induced in these SCRaMbLE strains.
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A Unified Multitude : Experimental Studies of Bacterial Chromosome OrganizationGarmendia, Eva January 2017 (has links)
Bacteria are many, old and varied; different bacterial species have been evolving for millions of years and show many disparate life-styles and types of metabolism. Nevertheless, some of the characteristics regarding how bacteria organize their chromosomes are relatively conserved, suggesting that they might be both ancient and important, and that selective pressures inhibit their modification. This thesis aims to study some of these characteristics experimentally, assessing how changes affect bacterial growth, and how, after changing conserved features, bacteria might evolve. First, we experimentally tested what are the constraints on the horizontal transfer of a gene highly important for bacterial growth. Second, we investigated the significance of the location and orientation of a highly expressed and essential operon; and we experimentally evolved strains with suboptimal locations and orientations to assess how bacteria could adapt to these changes. Thirdly, we sought to understand the accessibility of different regions of the bacterial chromosome to engage in homologous recombination. And lastly, we constructed bacterial strains with chromosomal inversions to assess what effect the inversions had on growth rate, and how bacteria carrying costly inversions could evolve to reduce these costs. The results provide evidence for different selective forces acting to conserve these chromosome organizational traits. Accordingly, we found that evolutionary distance, functional conservation, suboptimal expression and impaired network connectivity of a gene can affect the successful transfer of genes between bacterial species. We determined that relative location of an essential and highly expressed operon is critical for supporting fast growth rate, and that its location seems to be more important than its orientation. We also found that both the location, and relative orientation of separated duplicate sequences can affect recombination rates between these sequences in different regions of the chromosome. Finally, the data suggest that the importance of having the two arms of a circular bacterial chromosome approximately equal in size is a strong selective force acting against certain type of chromosomal inversions.
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The Importance of Bacterial Replichore BalanceCerit, Ender Efe January 2021 (has links)
In most bacterial pathogens, the genome is comprised within a single circular chromosome which is typically organized by the origin-to-terminus axis that divides the chromosome into equally-sized arms of replication (replichores). This similarity in length is presumed to be required for the synchronization of the two replication forks to meet at the terminus for efficient chromosome segregation. Transfer of genes between organisms, different from the route of parent to offspring, is called horizontal gene transfer (HGT). Acquiring foreign DNA through HGT is an important factor for the evolution of virulence in bacteria since it provides access to new features such as new toxins and antibiotic resistance genes. Chromosomes of many pathogenic bacteria such as Salmonella spp. carry such horizontally-transferred DNA fragments called pathogenicity islands. However, after such HGT events, the existing organization of chromosome can be disrupted and an imbalance between the two halves of the circular chromosome might occur. The predicted outcome of a replichore imbalance is the retardation of growth which in turn might result in the out-competition by other faster-growing bacteria in the environment. For that reason, we have investigated the association of the fitness cost and the replichore imbalance with isogenic strains with varying degrees of inter-replichore inversions. Our results showed that there is a correlation between the magnitude of replichore imbalance and fitness cost, for example 2.49-fold imbalance (one replichore 2.49-fold longer than the other) resulted in 11% reduction of fitness in comparison with balanced replichores. Therefore, our data suggest that the replichore imbalance could be utilized to predict the fitness cost of HGT events.
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