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Mechanisms of assembly of TCF-containing transcription factor complexesRoberts, Elizabeth Claire January 1999 (has links)
No description available.
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Molecular Mechanisms for the Evolution of DNA Specificity in a Transcription Factor FamilyMcKeown, Alesia 14 January 2015 (has links)
Transcription factors (TFs) bind to specific DNA sequences near target genes to precisely coordinate their regulation. Despite the central role of transcription factors in development and homeostasis, the mechanisms by which TFs have evolved to bind and regulate distinct DNA sequences are poorly understood.
This dissertation details the highly collaborative work to determine the genetic, biochemical and biophysical mechanisms by which distinct DNA-binding specificities evolved in the steroid receptor (SR) family of transcription factors. Using ancestral protein reconstruction, we resurrected and functionally characterized the historical transition in DNA-binding specificity between ancient SR proteins. We found that DNA-binding specificity evolved by changes in the energetic components of binding; interactions at the protein-DNA interface were weakened while inter-protein cooperativity was greatly improved.
We identified a group of fourteen historical substitutions that were sufficient to recapitulate the derived protein's binding function. Three of these substitutions, which we defined as function-switching, were sufficient to change DNA specificity; however, their introduction greatly decreased binding affinity and was deleterious for protein function. A group of eleven permissive substitutions, which had no effect on DNA specificity, allowed for the protein to tolerate the deleterious effects of the function-switching substitutions. They non-specifically increased binding affinity by improving interactions at the protein-DNA interface and increasing inter-protein cooperativity.
We then dissected the functional role of individual substitutions in both the function-switching and permissive groups. We first determined the binding affinity of all possible combinations of function-switching substitutions for a library of DNA sequences. This allowed for us to functionally characterize the sequence space that separated the ancestral and derived DNA-binding specificities as well as identify the genetic determinants for DNA specificity. Lastly, we dissected the effects of the permissive substitutions on the energetics of DNA binding to determine the mechanisms by which they exerted their permissive effect. Together, this work provides insight into the molecular determinants of DNA specificity and identifies the molecular mechanisms by which these interactions changed during the evolution of novel specificity in an important transcription factor family.
This dissertation includes previously published and unpublished co-authored material. / 2016-01-14
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Defining the DNA binding energetics of the glucocorticoid receptorZhang, Liyang 01 December 2017 (has links)
DNA-binding proteins bind to specific sequences to direct their activity to defined loci in the genome. Regulation of gene expression, for example, is dependent on the recognition of specific DNA sequences by transcription factors (TFs). These TFs receive input from cellular signals to control panels of genes to meet the needs of the cells. Critical to this function is the recognition and binding of TFs to the correct DNA sequence. The main focus of this thesis is to quantitatively determine how proteins, including TFs, distinguish DNA sequences, and to understand how DNA sequence affect their function. Primarily using the Glucocorticoid receptor (GR) as the model TF, I developed novel methods to measure the DNA binding specificity over long binding sites. These methods: 1) Distinguished the sequence specificity of GR and closely related androgen receptor (AR), which helped to both account for differential genomic localization between the two factors, and explained how GR can functionally substitute for AR in castration-resistant prostate cancer (Chapter II); 2) Explored the effect of DNA sequence on GR-regulated transcription through the specification of monomeric versus dimeric binding. Sequence motifs that bias GR binding toward the monomeric state were discovered (Chapter III); 3) Demonstrated a conserved role of intrinsic specificity in directing the degree of GR genomic occupancy in vivo in a fixed chromatin context (Chapter V); 4) Quantitatively modeled and decoupled the DNA binding and cleavage specificities of CRISPR-Cas9 system, providing a rapid pipeline to characterize the genome-editing reagents (Chapter IV). In summary, we showed here that DNA binding specificity is only the initial step in directing the activity of the bound protein. Beyond the affinity-based recruitment, DNA sequences can regulate the protein activity through alternative mechanisms, such as modulating the binding cooperativity, or directly serving as an allosteric ligand for protein function that is independent of DNA binding affinity.
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A Phage Display System to Profile the DNA-binding Specificities of C2H2 Zinc FingersLam, Kathy 07 January 2011 (has links)
Knowing the sequence specificities of transcription factors allows us to surmise their functions and establish their regulatory roles in genomes. The most common DNA-binding domain among eukaryotic transcription factors is the Cys2His2 zinc finger domain; however, despite their prevalence, the specificities of the majority of Cys2His2 zinc finger proteins remain unknown due to the difficulty in assaying them. My objective was to develop a new phage displayed-based assay, in which individual Cys2His2 domains are displayed on phage in an otherwise constant three-finger protein scaffold. In Chapter 2, I discuss evidence for the modularity of the Cys2His2 domain, since my assay requires that zinc fingers be modular. In Chapter 3, I describe my results on the development of this phage display-based assay. This work provides support for a new strategy to determine the specificities of individual zinc fingers, which can be used to infer specificities for multi-finger Cys2His2 proteins.
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A Phage Display System to Profile the DNA-binding Specificities of C2H2 Zinc FingersLam, Kathy 07 January 2011 (has links)
Knowing the sequence specificities of transcription factors allows us to surmise their functions and establish their regulatory roles in genomes. The most common DNA-binding domain among eukaryotic transcription factors is the Cys2His2 zinc finger domain; however, despite their prevalence, the specificities of the majority of Cys2His2 zinc finger proteins remain unknown due to the difficulty in assaying them. My objective was to develop a new phage displayed-based assay, in which individual Cys2His2 domains are displayed on phage in an otherwise constant three-finger protein scaffold. In Chapter 2, I discuss evidence for the modularity of the Cys2His2 domain, since my assay requires that zinc fingers be modular. In Chapter 3, I describe my results on the development of this phage display-based assay. This work provides support for a new strategy to determine the specificities of individual zinc fingers, which can be used to infer specificities for multi-finger Cys2His2 proteins.
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Defining Gsx2 Mechanisms that Regulate Neural Gene Expression and Progenitor Maintenance in the Mouse Ventral TelencephalonSalomone, Joseph R. 22 October 2020 (has links)
No description available.
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