Global ETD Search

111	The Natural and Pharmacological Inhibition of Ribonucleotide Reductase Misko, Tessianna, Misko 01 February 2019 (has links) No description available. Biomedical Research Pharmacology
112	CHARACTERIZATION AND STUDY OF THE PHYSIOLOGICAL ROLE OF CTL0511, A CHLAMYDIAL PROTEIN PHOSPHATASE TYPE 2C Claywell, Ja 01 May 2019 (has links) (PDF) Chlamydia are obligate intracellular bacterial pathogens that are responsible for infectious blindness, sexually transmitted infections, and acute respiratory disease in humans. These pathogens undergo an essential biphasic developmental cycle differentiating between two functionally distinct forms known as the infectious elementary body (EB) and the replicative reticulate body (RB). Identifying the signals and regulatory mechanisms that enable Chlamydia to establish infection, differentiate between the two developmental forms, and survive within the host cell is critical to understanding chlamydial pathogenesis and developing future therapeutic strategies. In pathogenic bacteria, serine, threonine, and tyrosine (Ser/Thr/Tyr) protein kinases and phosphatases are critical for development, metabolism, and virulence. Chlamydia encode two validated protein kinases (pkn1 and pknd), a putative protein phosphatase (ctl0511; CppA), and appear capable of global phosphorylation that differs between the developmental forms. While these findings support a role for protein phosphorylation in chlamydial pathogenesis, a validated cognate protein phosphatase for Pkn1 and PknD mediating reversible phosphorylation was lacking. We hypothesized that CppA is the partner phosphatase for the chlamydial protein kinases, and in this study we validated and characterized CppA as a broad specificity protein phosphatase type 2C. Using in vivo and in vitro approaches we demonstrated that CppA acts on P-Ser/Thr/Tyr residues and can dephosphorylate multiple chlamydial protein substrates including PknD and the FHA 2 domain of CdsD, a component of the type 3 secretion apparatus. The importance of CppA for chlamydial growth and development was determined using a chemical “knock-out” approach and study of CppA missense mutations identified in slow growing C. trachomatis L2 chemical mutants. Treatment of C. trachomatis L2, C. trachomatis D, and C. muridarum with CppA inhibitors significantly reduced progeny levels and inclusion size in a time dependent manner with more significant growth inhibition in the first 12 hours post infection. Collectively, our findings support that CppA works in conjunction with PknD, and likely Pkn1, to mediate reversible phosphorylation of multiple protein substrates leading to changes in chlamydial physiology that appear to be key for early steps in development. Bacterial development Chlamydia trachomatis Protein kinase Protein phosphatase Protein phosphorylation Small molecule inhibitors
113	Structure-Activity Relationship Analyses of Rhosin, a RhoA GTPase Inhibitor, Reveals a New Class of Antiplatelet Agents Dandamudi, Akhila 06 June 2023 (has links) No description available. Medicine Small molecule inhibitor Chiral enantiomer RhoGTPase signaling Platelet activation antiplatelet thrombosis
114	Identification of Small Molecules that Inhibit Prostate Cancer Cell Proliferation Zelaya, Rainel 01 January 2014 (has links) Prostate cancer is the second most often diagnosed cancer and internationally the sixth foremost cause of cancer death in males, as of 2011. Within the United States it is the most common form of cancer in men with 186,000 new cases and with an overall 28,600 deaths in 2008, and it is the second leading kind of cancer-related death in men. The widespread threat that prostate cancer poses against men across the globe cannot be understated, and its initiation and progression must be understood in order to truly comprehend its implicated risks and possible forms of treatment. As its name implies, prostate cancer is a form of cancer that develops in the prostate gland located in the male reproductive system. Its progress starts when standard semen-secreting prostate gland cells mutate into cancer cells. Although its developments may start at the prostate gland, cancer cells may metastasize to other parts of the body through circulation systems such as the lymph nodes. The main sites of metastasis for prostate cancer include the adrenal gland, the bones, the liver and the lungs. Although there are treatments available for prostate cancer, there is no definitive cure. The primary goal of this project was to find an alternative form of treatment, which is what will be necessary to combat this cancer. Medicine and Health Sciences
115	Targeting the formyl peptide receptor 1 for treatment of glioblastoma Ahmet, Djevdet S. January 2021 (has links) Background and Aims Gliomas account for over half of all primary brain tumours and have a very poor prognosis, with a median survival of less than two years. There is an urgent and unmet clinical need to develop new therapies against glioma. Recent reports have indicated the overexpression of FPR1 in gliomas particularly in high grade gliomas. The aim of this project was to identify and synthesise small molecule FPR1 antagonists, and to demonstrate a proof of principle in preclinical in vitro and in vivo models that small molecule FPR1 antagonism can retard expansion of glioma. Methods A number of small molecule FPR1 antagonists were identified by in silico design, or from the literature and then were prepared using chemical synthesis. FPR1 antagonists were evaluated in vitro for their ability to abrogate FPR1-induced cellular responses in a range of models including calcium mobilisation, cell migration, and invasion. The efficacy of FPR1 antagonist ICT12035 in vivo was assessed in a U-87 MG subcutaneous xenograft model. Results Virtual high throughput screening using a homology model of FPR1 led to the identification of two small molecule FPR1 antagonists. At the same time chemical synthesis of two other antagonists, ICT5100 and ICT12035 as well as their analogues were carried out. The FPR1 antagonists were assessed in calcium flux assay which gave an insight into their structure-activity relationship. Further investigation of both ICT5100 and ICT12035 demonstrated that both small molecule FPR1 antagonists were effective at abrogating FPR1-induced calcium mobilisation, migration, and invasion in U- 87 MG in vitro models in a dose-dependent manner. ICT12035 is a particularly selective and potent inhibitor of FPR1 with an IC50 of 37.7 nM in calcium flux assay. Additionally, it was shown that the FPR1 antagonist ICT12035 was able to arrest the growth rate of U-87 MG xenografted tumours in mice. Conclusion The results demonstrate that targeting FPR1 by a small molecule antagonist such as ICT12035, could provide a potential new therapy for the treatment of glioblastoma. / Yorkshire Cancer Research Formyl peptide receptor 1 Annexin-A1 Glioblastoma Spheroid Drug discovery Synthetic medicinal chemistry Small molecule antagonists
116	Lipid-Based Delivery Systems for Therapeutic Small Molecules and RNA Zhang, Chi January 2022 (has links) No description available. Pharmaceuticals
117	Chemical Interrogation Of Sporulation And Cell Division In Streptomyces Jani, Charul January 2015 (has links) Cell division is essential for spore formation but not for viability in the filamentous streptomycetes bacteria. Failure to complete cell division instead blocks spore formation, a phenotype that can be visualized by the absence of gray (in Streptomyces coelicolor) and green (in Streptomyces venezuelae) spore-associated pigmentation. The streptomycetes divisome is however, similar to that of other prokaryotes. We hypothesized chemical inhibitors of sporulation in model streptomycetes might interfere with cell division in rod shaped bacteria. To test this, we investigated 196 compounds that inhibit sporulation in Streptomyces coelicolor. We show that 19 of these compounds cause filamentous growth in Bacillus subtilis, consistent with impaired cell division. One of the compounds is a DNA damaging agent and inhibits cell division by activating the SOS response. The remaining 18 act independently of known stress responses and may therefore act on the divisome or on divisome positioning and stability. Three of the compounds (Fil-1, 2 and 3) confer distinct cell division defects on B. subtilis. They also block B. subtilis sporulation, which is mechanistically unrelated to the sporulation pathway of streptomycetes but which is also dependent on the divisome. We discuss ways in which these differing phenotypes can be used in screens for cell division inhibitors. In addition to the molecules affecting the divisome, DNA and cell wall damage also affects the process indirectly by temporarily halting the cell division. To further explore the cell division regulation in stressful conditions, we carried the complete transcriptomic analysis of S. venezuelae after the DNA damage. The observed changes in the gene expression as a result of the DNA damage paves the way for identification of the DNAdamage induced cell division inhibitor in streptomycetes. / Thesis / Doctor of Philosophy (PhD)
118	Small molecule-mediated upregulation of G3BP1 as a therapy for ALS Shokri, Asana 10 1900 (has links) Les troubles neurodégénératifs, tels que la sclérose latérale amyotrophique (SLA) et la démence frontotemporale (DFT), ont été associés aux protéines de liaison à l'ARN (RBP). Les principales caractéristiques de la SLA sont l'agrégation d'une protéine de liaison à l'ARN appelée protéine de liaison TAR (TDP-43). Il a été démontré que TDP-43 se lie à G3BP1, un facteur de nucléation pour l'assemblage des granules de stress, pour le stabiliser. Les granules de stress sont des structures séparées par phases qui se forment dans des conditions stressantes et favorisent la survie cellulaire. Une altération de l’assemblage des granules de stress et une réduction du G3BP1 sont signalées dans la SLA. Cette réduction est due à un défaut dans les transcriptions codantes pour G3BP1 stabilisant TDP-43. Par conséquent, une réponse défaillante des granules de stress pourrait jouer un rôle majeur dans la maladie. Ainsi, ce projet de recherche se concentre sur la restauration de G3BP1, dont la déplétion est liée à la perte de fonction de TDP-43. En utilisant des composés de petites molécules identifiés lors d'une campagne de dépistage de médicaments, nous cherchons à augmenter l'expression de G3BP1, rétablissant ainsi le mécanisme SG endogène et favorisant la survie neuronale. La découverte de candidats principaux (NPX-047, NPX-000-115 et NPX-001-280) qui sauvent efficacement l'expression et la fonction de G3BP1 est prometteuse pour des thérapies potentielles contre la SLA. Ces composés ont été testés sur des cellules SHSY5Y traitées avec du si-TDP, mais aucune récupération de l'ARNm de G3BP1 n'a été observée malgré des niveaux plus élevés de signaux de luciférase. Ainsi, une enquête approfondie sur les divergences dans nos résultats constitue notre prochaine étape, ce qui n’a pas été possible pendant la durée limitée de cette mémoire. De plus, les cibles non ciblées de ces composés seront étudiées à l’aide du séquençage Bru Chase. Dans l’ensemble, cette étude explore de nouvelles stratégies pour restaurer l’expression de G3BP1, offrant ainsi une voie potentielle d’intervention thérapeutique dans la SLA. / Neurodegenerative disorders, such as Amyotrophic Lateral Sclerosis (ALS) and Frontotemporal Dementia (FTD), have been associated with RNA-binding proteins (RBPs). Major hallmark of ALS is aggregation of an RNA-binding protein called TAR binding protein (TDP-43). TDP-43 has shown to bind to G3BP1, a nucleating factor for stress granule assembly, to stabilize it. Stress granules (SGs) are phase separated structures that form under stressful conditions and promote cell survival. Impaired stress granules assembly and reduced G3BP1 is reported in ALS. This reduction is due to a defect in TDP-43 stabilizing G3BP1 encoding transcripts; thus, a failed stress granule response could have a major role in the disease. Thus, this research focuses on restoring G3BP1, whose depletion is linked to TDP-43 loss of function. By utilizing small-molecule compounds identified through a drug screening campaign, we seek to increase G3BP1 expression, consequently reinstating the endogenous SG mechanism and promoting neuronal survival. The discovery of lead candidates (NPX-047, NPX-000-115, and NPX-001-280) that effectively rescue G3BP1 expression and function offers promise for potential ALS therapies. These compounds were tested on SH-SY5Y cells treated with si-TDP however no rescue of G3BP1 mRNA was observed despite higher levels of luciferase signals. Thus, in-depth investigation of discrepancies in our results is our next step which was not possible during the limited timeline of this thesis. In addition, off-targets of these compounds will be investigated using BruChase-sequencing. Overall, this study explores novel strategies to restore G3BP1 expression, providing a potential avenue for therapeutic intervention in ALS. ALS FTD TDP-43 G3BP1 SG Petite molécule SH-SY5Y Small-molecule
119	Inhibition of antibody light chain amyloid formation in vitro Shrivastav, Anjaney 08 March 2024 (has links) Light chain (AL) amyloidosis is a disease that occurs due to the presence of a small plasma-cell clone, which produces amyloidogenic light chains. These chains can misfold and aggregate, leading to the deposition of amyloid fibrils in tissues. If left untreated or if treatment is ineffective, this can result in irreversible organ dysfunction and eventual death. Current therapeutic treatments generally target and remove the clonal plasma cell population responsible for secreting full-length light chains which is not always effective or safe, however, a different approach to halt pathological LC misfolding would be to inhibit the amyloidogenesis cascade at its starting point. Small molecules have been identified that have the ability to bind to highly conserved residues in the interface between heavy and light chains which can be used to potentially impede the process of amyloid fibril deposition before the native FL LC can misfold or undergo proteolysis to form amyloid fibrils. To test whether small-molecule kinetic stabilizers are effective in stabilizing light chains, we measured the ability of the small molecule to bind to LCs, and the ability of light chains to aggregate and unfold in the absence and presence of small-molecule. Our findings suggest that the binding of stabilizers to the interface between variable domains of the LC dimer can increase equilibrium stability and decrease the rate of aggregation, thereby delaying the onset of amyloid formation. Molecular biology AL amyloidosis Amyloid fibrils Endoproteolysis Immunoglobulin Small-molecule kinetic stabilizers Systemic amyloidosis
120	Identification and Characterization of Novel Antiretroviral Compounds: from Small Molecule Library Screening to Rationally Designed Compounds Jegede, Oyebisi 27 July 2007 (has links) No description available. HIV/AIDS Drug Discovery Small Molecule Library Screening Highly Active Antiretroviral Therapy

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