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New Insights into the Structure, Function and Evolution of TETR Family Transcriptional RegulatorsYu, Zhou 21 April 2010 (has links)
Antibiotic resistance is a worsening threat to human health. Increasing our understanding of the mechanisms causing this resistance will be of great benefit in designing methods to evade resistance and in developing new classes of antibiotics. In this thesis, I have used the TetR Family Transcriptional Regulators (TFRs), which constitute one of the largest antibiotic resistance regulator families, as a model system to study the structure, function and evolution of antibiotic resistance determinants. I performed a thorough examination of the variation and conservation seen in TFR sequences and structures using computational approaches. Through structure comparison, I have identified the most conserved features shared by the TFR family that are crucial for their stability and function. Based on my findings on conserved TFR structural features, a quantitative assay of binding affinity determination was developed. Through sequence comparison and a residue contact map method, I discovered the existence of a conserved residue network that correlates well with the known allostery pathway of TetR. This predicted allosteric communication network was experimentally tested in TtgR. I have also developed methods to identify TFR operator sequences through genomic comparisons and validated my prediction through experiments. In addition, I have developed an in vivo system that can be used to identify and characterize proteins that mediate resistance to almost any antibiotic. This system is simple, fast, and scalable for high-throughput applications, and could be used to discover a wide range of novel antibiotic resistance mechanisms. The principles that I applied to the TFR family could also be applied to other protein families.
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New Insights into the Structure, Function and Evolution of TETR Family Transcriptional RegulatorsYu, Zhou 21 April 2010 (has links)
Antibiotic resistance is a worsening threat to human health. Increasing our understanding of the mechanisms causing this resistance will be of great benefit in designing methods to evade resistance and in developing new classes of antibiotics. In this thesis, I have used the TetR Family Transcriptional Regulators (TFRs), which constitute one of the largest antibiotic resistance regulator families, as a model system to study the structure, function and evolution of antibiotic resistance determinants. I performed a thorough examination of the variation and conservation seen in TFR sequences and structures using computational approaches. Through structure comparison, I have identified the most conserved features shared by the TFR family that are crucial for their stability and function. Based on my findings on conserved TFR structural features, a quantitative assay of binding affinity determination was developed. Through sequence comparison and a residue contact map method, I discovered the existence of a conserved residue network that correlates well with the known allostery pathway of TetR. This predicted allosteric communication network was experimentally tested in TtgR. I have also developed methods to identify TFR operator sequences through genomic comparisons and validated my prediction through experiments. In addition, I have developed an in vivo system that can be used to identify and characterize proteins that mediate resistance to almost any antibiotic. This system is simple, fast, and scalable for high-throughput applications, and could be used to discover a wide range of novel antibiotic resistance mechanisms. The principles that I applied to the TFR family could also be applied to other protein families.
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Ligand selective regulation of cell growth by the Ah receptor through activation of TGFβ signaling / Ligand selective regulation of cell growth by the Ah receptor through activation of TGF-beta signalingKoch, Daniel C. 28 March 2015 (has links)
The Aryl hydrocarbon receptor (AhR) is a ligand-activated transcription factor and member of the basic helix-loop-helix Per/ARNT/Sim (bHLH/PAS) family of chemosensors and developmental regulators. As a member of the PAS domain family of transcription factors responsive to exogenous signals, the AhR exerts influence on many processes relating to cellular fate.
The activation of AhR is widely associated with toxic endpoints related to dioxin exposure. However, the AhR also activates endogenous gene programs related to development, cellular growth, and differentiation. The AhR is able to bind a variety of ligands, leading to a wide range of biological outcomes. Recent reports have shown that the AhR can mediate tumor suppressive effects. As a ligand-activated transcription factor, the AhR has the potential to actuate a variety of transcriptional programs that are dependent on the AhR ligand.
Our central hypothesis is that AhR ligands can be identified that are capable of initiating tumor suppressive functions of the AhR.
We utilized complementary cell-based and in silico virtual screening approaches to identify potential AhR ligands. We developed homology models of the AhR ligand-binding domain (LBD) for virtual ligand screening (VLS) of small molecule libraries. This led to the identification of new AhR ligands 5,7- dihydroxyflavanone!and 5-hydroxy-7-methoxyflavone. Additional small molecule libraries were screened in parallel that led to identification of flutamide as a putative AhR ligand. Flutamide is clinically approved for the treatment of prostate cancer due to its ability to antagonize androgen receptor mediated transcription. We investigated the biological effects of flutamide in AhR positive cancer cells that do not express the androgen receptor and found that flutamide inhibited the growth of HepG2 cells. Suppression of AhR expression reversed the anti-proliferative effects of flutamide.
We tested 15 structural analogs of flutamide, including the flutamide metabolite 2-hydroxyflutamide for activation of AhR transcriptional activity. Flutamide is unique in its ability to activate the AhR, and suppresses hepatoma cell growth. These data suggests that flutamide-induced AhR transcriptional activity is required to initiate the tumor suppressive effects. We examined changes in cell cycle checkpoint proteins after flutamide treatment and discovered increased expression of cell cycle inhibitory proteins p27[superscript Kip1] and p15[superscript INK]. We also found that transforming Growth Factor β1 (TGFβ1), which
regulates both p27[superscript Kip1] and p15[superscript INK], is upregulated by flutamide. We demonstrate
that TGFβ1 is upregulated by flutamide in an AhR-dependent manner and is
required for suppression of proliferation by flutamide. We identify specific and
unique transcriptional signatures of the AhR upon activation by flutamide, that
are distinct from the potent AhR agonist 2,3,7,8-Tetrachlorodibenzo-p-dioxin
(TCDD).
In summary, we characterize flutamide as an AhR ligand and demonstrate
its AhR-dependent tumor suppressive effects in hepatoma cells. We provide the
first direct evidence that AhR regulates TGFβ signaling in a ligand dependent
manner. We demonstrate that the AhR-induced downstream transcriptional
signature and subsequent biological effects are specific to the AhR ligand. Our
studies have broad impact for characterizing the AhR as a new therapeutic target
in hepatocellular carcinoma. / Graduation date: 2013 / Access restricted to the OSU Community at author's request from March 28, 2013 - March 28, 2015
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