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Novel Wittig and Organocatalytic Methodologies for the Synthesis of Chemotherapeutic CompoundsNielsen, Alexander J. January 2019 (has links)
This thesis is primarily focused on the development of Wittig methodologies and the applications of the product alkenes in organocatalysis and drug discovery. Herein is described an aqueous Wittig methodology for the synthesis of α-methylstilbenes and their use in the preparation of novel triazole stilbene inhibitors of aromatase, a clinically validated target for the treatment of estrogen receptor positive breast cancer. As well, a one-step, stereoselective synthesis of alkenyl phenols was developed. The method provides easy access to a variety of compounds that contain this synthetically and biologically important functionality, including natural product phenolic stilbenes. In turn, alkenyl phenols were used as a key component in a novel organocatalytic methodology for the synthesis of cyclobutanes in good yields and high enantioselectivity. Notably, this is one of relatively few asymmetric, catalytic methods for cyclobutane synthesis. Preliminary biological activity of some of these cyclobutane derivatives is reported, including promising anti-cancer activity. Finally, a ten-step total synthesis of the Amaryllidaceae alkaloid (+)-trans-dihydronarciclasine was completed. The synthesis features an organocatalytic Michael-aldol cascade on a cinnamaldehyde derivative, which was prepared using a Wittig methodology previous reported by the McNulty group. Importantly, this compound was found to be one of the most potent anti-Zika compounds reported to date. Future work should focus on improving the potency and selectivity of the various aforementioned chemotherapeutics, with concurrent efforts to build upon the novel methodologies discussed herein. / Thesis / Doctor of Philosophy (PhD) / The Wittig reaction is one of the best ways to make alkenes, a type of reactive bond between two carbon atoms. A new Wittig reaction was developed and used in the preparation and discovery of potent inhibitors of aromatase, an enzyme responsible for the proliferation of many breast cancers. As well, another Wittig methodology was created for the straightforward synthesis of an otherwise difficult to prepare class of alkenes. In turn, these types of alkenes were used in a novel preparation of cyclobutanes, a chemical structure that is difficult to make but can impart useful properties to drugs and materials. Finally, a Wittig reaction previously reported by the McNulty group was used as part of a chemical synthesis of trans-dihydronarciclasine, a rare natural product isolated from daffodils. Trans-dihydronarciclasine was discovered to have antiviral activity and is one of the most potent inhibitors of the Zika virus discovered to date.
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Investigating the Molecular Mechanism of Novel Quinuclidinone Derivatives in Lung Cancer Cells with Different p53 StatusSoans, Eroica 22 September 2010 (has links)
No description available.
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Advancing a methodology for implant-triggered cancer treatment with Bioorthogonal Palladium-Labile prodrugsBray, Thomas Llewelyn January 2018 (has links)
Chemotherapeutics are potent molecules capable of systematically treating cancer. As healthy tissues contain features also inherent to cancer cells, treatment often results in unwanted sideeffect. As chemotherapeutic side-effect produces significant harm and often limits optimal drug dosing, new strategies must be developed to improve treatment selectivity. A prodrug strategy provides one option to improve the selectivity of an established chemotherapeutic. By modifying a pharmaceutically active drug, interaction with biology may be functionally masked. Subsequent ‘un-masking’ the prodrug exclusively at the intended treatment site may direct treatment only to where the anticancer effect is required. This thesis progresses the novel approach of bioorthogonal organometallic (BOOM) prodrug activation. A metal catalyst and masked chemotherapeutic constitute reaction partners to provide a new strategy for intratumoural prodrug activation. Whereby the prodrug and metal catalyst are independently non-cytotoxic, in combination the prodrug undergoes catalytic activation to deliver an anticancer affect. By positioning the metal catalyst within a tumour (i.e. by microsurgery), an administered masked prodrug sensitive to catalyst-mediated activation could allow for ‘targeted’ chemotherapy localised to the tumour site. The design, synthesis and study of new BOOM prodrug candidates are reported herein. Novel protecting groups are developed to enhance drug masking to biology and subsequent catalyst-mediated activation. Prodrug screening studies are carried out in cancer cell culture models, with zebrafish and in ex vivo rodent model tumour explants. The catalyst, a palladium (Pd0) functionalised bead system, is optimised for enhanced activation, drug release and in vivo implantation. The potentially infinite generation of active chemotherapeutics exclusively in tumour would increase the efficacy of treatment whilst reducing harmful effect on healthy tissue.
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Manganese Porphyrin, MnTE-2-PyP5+, Enhances Chemotherapeutic Response in Hematologic MalignanciesJaramillo, Melba Concepcion Corrales, Jaramillo, Melba Concepcion Corrales January 2017 (has links)
The prognosis for multiple myeloma (MM) and the activated B-cell subtype of diffuse large B-cell lymphoma (ABC DLBCL) is poor. Gene expression profiling studies have identified that the transcription factor, nuclear factor kappa B (NF-κB) is overexpressed and confers a poor prognosis in MM and ABC DLBCL. NF-κB regulates the transcription of genes involved in cell proliferation and survival. Thus, several groups have tried to identify and/or develop agents that target NF-κB to improve therapy and patient prognosis for MM and ABC DLBCL. Our laboratory has shown that the manganese porphyrin MnTE-2-PyP5+ inhibits NF-κB in a murine lymphoma cell culture model and enhances tumor cell death in combination with dexamethasone and cyclophosphamide, two agents that are routinely used to treat these neoplasms. MnTE-2-PyP5+ inhibits NF-κB by glutathionylating p65, a member of the NF-κB family. The objective of the following studies was to determine whether MnTE-2-PyP5+ enhances the chemotherapeutic response in human MM and ABC DLBCL cells that overexpress and depend on NF-κB for survival. The following studies demonstrate that MnTE-2-PyP5+ glutathionylates and inhibits NF-κB in human MM and ABC DLBCL cells. MnTE-2-PyP5+ also synergizes with several MM and DLBCL chemotherapeutics, including dexamethasone, cyclophosphamide, vincristine and bortezomib to enhance cell death. The data from these human cell lines will provide the basis for future studies to test MnTE-2-PyP5+ in animal models and for translating MnTE-2-PyP5+ to the clinic.
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Potent organometallic osmium compounds induce mitochondria-mediated apoptosis and S-phase cell cycle arrest in A549 non-small cell lung cancer cellsvan Rijt, S.H., Romero-Canelón, I., Fu, Y., Shnyder, Steven, Sadler, P.J. 06 March 2014 (has links)
Yes / The problems of acquired resistance associated with platinum drugs may be addressed by chemotherapeutics based on other transition metals as they offer the possibility of novel mechanisms of action. In this study, the cellular uptake and induction of apoptosis in A549 human non-small cell lung cancer cells of three promising osmium(II) arene complexes containing azopyridine ligands,[Os(Z6-arene)( p-R-phenylazopyridine)X]PF6, where arene is p-cymene or biphenyl, R is OH or NMe2, and X is Cl or I, were investigated. These complexes showed time-dependent (4–48 h) potent anticancer activity with highest potency after 24 h (IC50 values ranging from 0.1 to 3.6 mM). Cellular uptake of the three compounds as quantified by ICP-MS, was independent of their log P values (hydrophobicity). Furthermore, maximum cell uptake was observed after 24 h, with evident cell efflux of the osmium after 48 and 72 h of exposure, which correlated with the corresponding IC50 values. The most active compound 2, [Os(Z6-p-cymene)(NMe2-phenylazopyridine)I]PF6, was taken up by lung cancer cells pre-dominately in a temperature-dependent manner indicating that energy-dependent mechanisms are important in the uptake of 2. Cell fractionation studies showed that all three compounds accumulated mainly in cellular membranes. Furthermore, compound 2 induced apoptosis and caused accumulation in the S-phase of the cell cycle. In addition, 2 induced cytochrome c release and alterations in mito-chondrial membrane potential even after short exposure times, indicating that mitochondrial apoptotic pathways are involved. This study represents the first steps towards understanding the mode of action of this promising class of new osmium-based chemotherapeutics.
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Controle de qualidade da prova de sensibilidade e antibióticos e quimioterápicos / Quality control of susceptibility test of antibiotics and chemotherapeuticsMamizuka, Elsa Masae 11 February 1983 (has links)
Não consta resumo na publicação. / Abstract not available.
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Role and Regulation of SnoN/SkiL and PLSCR1 Located at 3q26.2 and 3q23, Respectively, in Ovarian Cancer PathophysiologyKodigepalli, Madhav Karthik 18 September 2014 (has links)
Ovarian cancer is one of the most common causes of gynecological cancer related deaths in women. In 2014, the estimated number of deaths due to ovarian cancer is 14,270 with occurrence of over 22, 240 new cases (National Cancer Institute, http://seer.cancer.gov/statfacts/html/ovary.html). Despite improvement in treatment strategies, the 5-year survival rate is still below 50% mainly due to chemoresistance and relapse. Amplification of chromosomal region 3q26 is a common characteristic in various epithelial cancers including ovarian cancer. This region harbors various oncogenes including the TGFβ signaling mediators EVI1 and SnoN/SkiL, PKCι and PIK3CA amplified at 3q26.2 and 3q26.3, respectively, in ovarian cancers. Previous studies indicate that these genes can exhibit cooperative oncogenicity by cross-regulating one another and facilitating cancer development. Our earlier studies demonstrated that treatment of ovarian cancer cells with arsenic trioxide (As2O3) promotes cytoprotective autophagy regulated by induction of SnoN to antagonize the cytotoxic effects of As2O3. Since exact mechanisms underlying As2O3-induced SnoN expression and cytoprotective responses were unclear, we hypothesized that SnoN may be regulated by signaling pathways involving genes amplified at the 3q26 locus.
Phospholipid scramblase 1 (PLSCR1) is located at 3q23 proximal to the amplified 3q26 region. It had been implicated in disruption of plasma membrane asymmetry by mediating phospholipid scrambling, a process critical for cellular events such as blood coagulation and apoptosis. However, recent findings have led to more investigations on the role and regulation of PLSCR1 in cancer development and immune responses. PLSCR1 expression is regulated by various stimuli including growth factors (EGF, G-CSF, and SCF), cytokines (IFN), and differentiation-inducing agents (ATRA). Despite these studies, transcriptional regulation of PLSCR1 remains incompletely understood. Numerous studies have suggested a critical role for PLSCR1 in the pathophysiology of various cancers including leukemia, ovarian cancer, colorectal cancer, and metastatic liver cancer. However, the precise contribution of PLSCR1 and its regulation in ovarian cancer development is unclear. Since PLSCR1 (at 3q23) is located in close proximity to SnoN/SkiL (at 3q26.2), we hypothesized that PLSCR1 expression in ovarian cancer cells could be regulated by SnoN. Herein, we present studies that primarily focus on understanding the role and regulation of SnoN/SkiL (a TGFβ pathway regulator) and PLSCR1 (an interferon-regulated gene), which are located at 3q26.2 and 3q23, respectively, in epithelial ovarian cancer.
In Chapter 3, we determined that activation of the PI3K signaling pathway mediates SnoN expression and cytoprotective responses upon stimulation of ovarian cancer cells with As2O3. We first identified that As2O3 stimulation leads to activation of EGFR and its downstream signaling mediators as well as modulates its interaction with the adaptor proteins, ShcA and Grb2. Interestingly, while treatment with a general SFK inhibitor (PP2), reduced the As2O3-induced EGFR activation and SnoN induction, a more specific inhibitor SU6656 did not alter SnoN expression. Further, via studies utilizing specific inhibitors and siRNA targeting PI3K, we determined that inhibition of PI3K signaling pathway decreases SnoN induction and increases apoptosis in ovarian cancer cells in response to As2O3. This suggests that PI3K (PIK3CA) activity is required for the As2O3-mediated SnoN induction and the cell survival responses in ovarian cancer cells. Finally, we determined by siRNA-mediated knockdown that EGFR and MAPK1 alter As2O3-induced cell death response independently of SnoN induction.
In Chapter 4, via bioinformatic analyses, we identified that PLSCR1 DNA copy number and mRNA expression is elevated in ovarian cancer patients and cell lines relative to immortalized (Tag/hTERT) normal ovarian surface epithelial (OSE) cells. Interestingly, altered PLSCR1 DNA and mRNA levels were correlated with SnoN in ovarian cancers. We next identified that SnoN knockdown leads to a significant (~35%, P2O3 transcriptionally downregulates PLSCR1 in a ROS-independent mechanism. Furthermore, PLSCR1 knockdown, similar to SnoN knockdown increases ovarian cancer cell sensitivity to As2O3. PLSCR1 knockdown increases cleaved PARP (marker of apoptosis) with a consequent reduction in LC3-II levels (marker of autophagosomes). Collectively, these studies implicate PLSCR1 in the pathophysiology of ovarian cancers and in altering the chemotherapeutic responses in ovarian cancer cells.
PLSCR1 is an IFN-regulated gene and mediates antiviral/immune responses. More recent studies in plasmacytoid dendritic cells have implicated PLSCR1 in regulating TLR9 signaling upon stimulation with CpG ODN. However, whether PLSCR1 could mediate the innate immune responses upon stimulation with dsDNA remained unclear. In Chapter 5, we identified that stimulation of normal ovarian and mammary epithelial cells with dsDNA (empty plasmid) markedly induces PLSCR1 consequent with activation of IRF3, a downstream mediator of TLR signaling that transcriptionally regulates the expression of type 1 IFNs. Interestingly, IRF3 knockdown ablates the dsDNA-induced PLSCR1 expression suggesting that PLSCR1 induction in response to dsDNA could be mediated by IRF3. Additionally, we have determined that dsDNA stimulation induces nucleic acid sensing TLRs, TLR9 and TLR4 as well as IFN-α and IFN-β mRNAs. Interestingly, dsDNA stimulation did not induce PLSCR1 or IRF3 activation in ovarian cancer cells suggesting that the mechanisms of IRF3 activation and PLSCR1 induction in response to dsDNA might be dysregulated in ovarian cancers.
Collectively, our studies demonstrate a possible synergistic role of SnoN and PLSCR1 in ovarian cancer pathophysiology and suggest a potentially dysregulated role of PLSCR1 in the dsDNA-induced immune responses of malignant epithelial cells relative to normal epithelial cells. These studies could potentially lead to development of a novel combinatorial therapeutic strategy that targets both these molecules for improving treatment of patients with ovarian carcinoma.
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Genomic Aberrations at the 3q and 14q loci: Investigation of Key Players in Ovarian and Renal Cancer BiologyDutta, Punashi 01 January 2015 (has links)
Genomic aberrations are primary contributors to the pathophysiology of cancer [11]. Dysregulated expression of genes located within these aberrations are important predictors of chemoresistance, disease prognosis, and patient outcome [12]. This dissertation is focused on understanding the regulation and/or functions of specific genes located at dysregulated genomic regions such as 3q26 and 14q32 in the biology of ovarian and renal cancer, respectively.
Serous epithelial ovarian cancer (EOC) manifest amplification at the 3q26.2 locus [2], an observation consistent with the cancer genome atlas (TCGA) [13]. The most amplified gene in this region is EVI1 which has been extensively studied in hematological malignancies [2]. However, its contribution to the pathophysiology of solid cancers remains unknown. We hypothesized that dysregulated EVI1 and SnoN/SkiL expression (located at the 3q26.2 amplicon) leads to the altered cellular functional response, thereby contributing to the pathophysiology of ovarian cancer. Our group has previously shown that EVI1 splice forms may exhibit altered subcellular localization and functional properties relative to the wild type form [14]. In Chapter 3 of this dissertation, we identified that EVI1 splice forms could modulate epithelial-mesenchymal transition. Our findings indicate that siRNA construct targeting the splice junction between exon 2 of MDS1 to exon 2 of EVI1, (reduces the expression of MDS1/EVI1 and EVI1Del190-515 splice forms) increases epithelial cell markers while decreasing mesenchymal markers and reducing migratory potential of ovarian and breast cancer cells.
SnoN/SkiL, another gene overexpressed at the 3q26 is reported by our group to be induced upon As2O3 treatment in ovarian cancer cells via unknown mechanisms [15]. This induction of SnoN opposes the apoptotic cell death pathway induced by the drug treatment [15]. We have previously identified that the PI3K/AKT pathway (also dysregulated in ovarian cancer [16]) contributes to the up-regulation of SnoN upon treatment with As2O3 [17]. However, SnoN is regulated via multiple mechanisms including post-translational modifications [18]. Additionally, c-Ski (a homolog of SnoN) is regulated post-transcriptionally by numerous miRNAs in cancer cells [19-22]. In Chapter 4, we attempted to identify potential miRNAs that could regulate SnoN expression post-transcriptionally. We discovered that miR-494 reduces both SnoN mRNA and protein levels. Our experimental outcomes also demonstrate that miR-494 further sensitizes ovarian cancer cells to drug treatment.
Interestingly, miR-494 is located at the 14q32 region which has been shown to be down-regulated in renal cancers [23]. Several reports indicate miR-494 to be involved in tumor suppressive responses including apoptosis and cell cycle arrest in various cancers [24-26]. However, its role in renal cancer biology remains unknown. We hypothesized that miR-494 elicits a tumor suppressive response in renal cancer cells. Through our studies in Chapter 5, we demonstrate that miR-494 reduces cell viability and increases apoptotic response in renal cancer cells. We also show that miR-494 increases LC3B mRNA and protein levels. A 3’UTR luciferase assay indicated that LC3B may be a potential target of miR-494. Intracellular lipid droplets (LDs) increased in miR-494 expressing in a LC3B-dependent manner. This was accompanied with reduced intracellular cholesterol content, increased mitochondrial structural disorganization, and altered Drp1 localization.
The outcome of our findings have improved our understanding of the regulation and functional response of these genes/miRNAs (EVI1, SnoN, and miR-494) in ovarian and renal cancers. The studies reported in Chapter 5 identified a novel function of miR-494 in increasing LDs and reducing renal cell survival. However, additional studies are warranted to fully understand the underlying mechanism of increased LDs formation in miR-494 expressing cells and the implication of miR-494 and other miRNAs at the 14q32 region in renal cancer biology. In future, these studies will aid in the development of better treatment strategies which will contribute towards the management of cancer.
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Controle de qualidade da prova de sensibilidade e antibióticos e quimioterápicos / Quality control of susceptibility test of antibiotics and chemotherapeuticsElsa Masae Mamizuka 11 February 1983 (has links)
Não consta resumo na publicação. / Abstract not available.
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Secretory phospholipase A2 as a tumor specific trigger for targeted delivery of a novel class of liposomal prodrug anticancer etherlipidsGill, Jason H., Bibby, Michael C., Jensen, S.S., Shnyder, Steven 11 1900 (has links)
No / The use of many common clinically relevant chemotherapeutics is often limited due to insufficient delivery to the tumor and dose-limiting systemic toxicities. Therefore, therapeutics that specifically target tumor cells and are nontoxic to normal cells are required. Here, we report the development of a novel class of liposomes composed of lipid prodrugs, which use the increased secretory phospholipase A2 type IIA (sPLA2) activity of the tumor microenvironment as a trigger for the release of anticancer etherlipids (AEL). Treatment of sPLA2-secreting tumor cells in vitro with liposomes consisting of proAELs resulted in growth inhibition comparable with addition of the AELs alone. Using a specific sPLA2 inhibitor, we showed the low cytotoxicity of the nonhydrolyzed proAEL liposomes and have proven the sPLA2 dependency of the activation of proAELs to cytotoxic AELs. In addition, we showed that our proAEL liposomes circumvent the inherent hemolytic toxicities associated with the use of etherlipids, thereby allowing i.v. administration of such therapeutics as nontoxic prodrug liposomes. Furthermore, using a sPLA2-secreting human colon cancer xenograft model, we showed that the proAEL liposomes are capable of inducing a tumor growth delay in vivo. Taken together, these data support the validity of this novel tumor-selective liposomal prodrug delivery strategy. This new approach also provides a promising system for tumor-selective delivery and release of conventional chemotherapeutics encapsulated in the sPLA2-degradable prodrug liposomes.
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