Global ETD Search

71	Shape-Dependent Molecular Recognition of Specific Sequences of DNA by Heterocyclic Cations Miao, Yi 03 August 2006 (has links) SHAPE-DEPENDENT MOLECULAR RECOGNITION OF SPECIFIC SEQUENCES OF DNA BY HETEROCYCLIC CATIONS by YI MIAO Under the Direction of Dr. W. David Wilson ABSTRACT DB921 and DB911 are biphenyl-benzimidazole-diamidine isomers with a central para- and meta-substituted phenyl group, respectively. Unexpectedly, linear DB921 has much stronger binding affinity with DNA than its curved isomer, DB911. This is quite surprising and intriguing since DB911 has the classical curved shape generally required for strong minor groove binding while DB921 clearly does not match the groove shape. Several biophysical techniques including thermal melting (Tm), circular dichroism (CD), biosensor-surface plasmon resonance (SPR), and isothermal titration calorimetry (ITC) have been utilized to investigate the interactions between these compounds and DNA. The structure of the DB921-DNA complex reveals that DB921 binds to DNA with a reduced twist of the biphenyl for better fit of DB921 into the minor groove. A bound water molecule complements the curvature of DB921 and contributes for tight binding by forming H-bonds with both DNA and DB921. Structure-affinity relationship studies of a series of DB921 analogs show that the benzimidazole group is one of the key groups of DB921 for its strong binding to the minor groove. Thermodynamic studies show that the stronger binding of DB921 is due to a more favorable binding enthalpy compared to DB911 even though the complex formation with DNA for these compounds are all predominantly entropically driven. DB921 also has more negative heat capacity change than DB911. The initial studies of inhibition of the interaction between an AT hook peptide of HMGA proteins and its target DNA by a set of diamidine AT-minor groove binders using biosensor-SPR technique show that the inhibitory ranking order is consistent with that of binding affinity and linear-shaped DB921 still has excellent inhibitory effects. These heterocyclic cations rapidly inhibit the binding of DBD2 peptide to the DNA and may only block the specific AT binding of the peptide without hindering the non-specific binding interaction. The results of this project have shown that DB921 represents a new novel effective minor groove binder that does not fit the traditional model and is a potential inhibitor for DNA/protein complexes. INDEX WORDS: Molecular recognition, DNA binding, Minor groove binding, Linear shape, Compound curvature, Binding affinity, Binding kinetics, Thermodynamics, Surface plasmon resonance, Isothermal titration calorimetry, Inhibition small molecule minor groove binding energetics binding entropy binding free energy binding enthalpy Chemistry
72	Small Molecule Activation with Main Group Complexes Dureen, Meghan Adrienne 16 March 2011 (has links) The synthesis of monodentate biphenyl-amido proligands is reported as well as a series of complexes of lithium with these ligand systems. The solid-state molecular structure of these lithium amides are described as well as their use as synthons in the preparation of amido-arene aluminum complexes. Structural and spectroscopic data suggest that these species exhibit weak arene to metal donation. Attempts to generate aluminum cations from these species are detailed. A new synthetic route to titanium “constrained geometry” precatalysts was utilized to prepare a series of titanium complexes with similar pendant arene groups. The homopolymerization activity of these catalyst systems with ethylene and styrene is detailed. Combination of a sterically encumbered phosphine and large, electrophilic borane was used to effect heterolytic cleavage of disulfides to afford novel thiophosphoniumthioborate salts. A series of exchange reactions demonstrated the facile reversal of this reaction. Similar phosphine-borane systems are found to exhibit divergent reactivity with terminal alkynes, affording either phosphonium-alkynylborate salts from deprotonation or phosphonium-vinyl-borate zwitterions from addition. The scope of Lewis acid, Lewis base and alkyne combinations used to effect similar reactivity is detailed. It was found that the reaction of pyrroles, boranes, and alkynes formed similar addition products that were found to undergo further reactivity to afford C-vinyl pyrroles and nitrogen-boron bicyclic compounds. The synthesis of N-alkyl-bis(pentafluorophenyl)boryl amidinates is presented. The reactivity of these compounds with a variety of small molecules is reported. Reaction with CO2, CO, di-iso-propylcarbodiimide, tert-butyl isocyanide, and benzaldehyde as well as thermally-induced intramolecular rearrangement of these compounds affords a variety of novel nitrogen-boron heterocycles. main group small molecule activation catalysts ethylene polymerzation alkynes disulfides 0488
73	Small Molecule Activation with Main Group Complexes Dureen, Meghan Adrienne 16 March 2011 (has links) The synthesis of monodentate biphenyl-amido proligands is reported as well as a series of complexes of lithium with these ligand systems. The solid-state molecular structure of these lithium amides are described as well as their use as synthons in the preparation of amido-arene aluminum complexes. Structural and spectroscopic data suggest that these species exhibit weak arene to metal donation. Attempts to generate aluminum cations from these species are detailed. A new synthetic route to titanium “constrained geometry” precatalysts was utilized to prepare a series of titanium complexes with similar pendant arene groups. The homopolymerization activity of these catalyst systems with ethylene and styrene is detailed. Combination of a sterically encumbered phosphine and large, electrophilic borane was used to effect heterolytic cleavage of disulfides to afford novel thiophosphoniumthioborate salts. A series of exchange reactions demonstrated the facile reversal of this reaction. Similar phosphine-borane systems are found to exhibit divergent reactivity with terminal alkynes, affording either phosphonium-alkynylborate salts from deprotonation or phosphonium-vinyl-borate zwitterions from addition. The scope of Lewis acid, Lewis base and alkyne combinations used to effect similar reactivity is detailed. It was found that the reaction of pyrroles, boranes, and alkynes formed similar addition products that were found to undergo further reactivity to afford C-vinyl pyrroles and nitrogen-boron bicyclic compounds. The synthesis of N-alkyl-bis(pentafluorophenyl)boryl amidinates is presented. The reactivity of these compounds with a variety of small molecules is reported. Reaction with CO2, CO, di-iso-propylcarbodiimide, tert-butyl isocyanide, and benzaldehyde as well as thermally-induced intramolecular rearrangement of these compounds affords a variety of novel nitrogen-boron heterocycles. main group small molecule activation catalysts ethylene polymerzation alkynes disulfides 0488
74	Importance of the Structural Components of C-linked Glycopeptides to Specific-antifreeze Activity: From Glycopeptides to Small Molecule Inhibitors of Ice Recrystallization Trant, John F. 22 February 2012 (has links) One of the largest problems in current medicine is the shortage of organs for transplant due to technological limitations in the storage of organs for any length of time. A possible solution to this problem would involve cryopreservation. However, current cryopreservatives such as sucrose or DMSO have concerning cytotoxic issues that limit their possible applications. A major cause of cryoinjury is the uncontrolled recrystallization of inter and intra-cellular ice crystals that occurs during the thawing process leading to mechanical damage and dehydration. The Ben lab has thus been interested in the design of compounds that are capable of inhibiting this process but do not possess other undesirable properties found in the native compounds. These synthetic analogues have been shown to increase cellular viability post-thaw. A series of mixed α/β glycopeptides are prepared and analyzed for antifreeze properties. The results of this study imply that it is not the gross conformation of the glycopeptide that is responsible for activity, but rather that intramolecular relationships may be responsible for disrupting the reorganization of ice. A technique was devised for the incorporation of triazoles into the analogues to investigate the importance of the linker and to greatly simplify the synthesis of a library of glycoconjugates. It was found that the IRI activity of glycopeptides is very sensitive to the distance between carbohydrate and peptide backbone. The electron density at the anomeric oxygen is an important parameter with respect to intramolecular networks. A series of substituted galactosides is presented that modify the electronics of the anomeric oxygen. The results demonstrate that decreasing electron density at this position appears to improve IRI activity in a predictable manner. To better understand the remarkable IRI activity of a key analogue, it was systematically truncated. This study led to the serendipitous discovery of a series of very highly IRI active analogues that do not contain a peptide backbone. These compounds represent the first non-glycopeptides that can show very significant IRI activity even at very low concentrations. The final portion of the thesis reports the efforts towards the preparation of a carbasugar analogue of AFGP-8. Antifreeze Organic Synthesis Bioorganic chemistry Recrystallization inhibition carbohydrates small molecule glycopeptide beta peptide CuAAC
75	Targeting Inducible Heat Shock Protein 70 in Cancer and Dengue Virus Pathogenesis with a Novel Small Molecule Inhibitor Howe, Matthew K. January 2015 (has links) <p>Inducible Heat shock protein (Hsp70i) is a protein chaperone that is utilized during tumorigenesis and viral infections for efficient propagation. Overexpression of Hsp70i is observed in a wide spectrum of human tumors, and this overexpression correlates with metastasis, poor outcomes, and resistance to chemotherapy in patients. Hsp70i aids in cancer cell propagation through regulation of anti-apoptotic and cell survival pathways. Furthermore, Hsp70i is induced following infection for several viruses and aids viral propagation, in part through regulation of anti-apoptotic pathways as well as promoting the folding of newly synthesized proteins. Due to the parallel role of Hsp70i in both cancer and viral pathogenesis, identification of small-molecule inhibitors selective for Hsp70i could provide tools for the development of novel therapeutics and further elucidate the role of Hsp70i in both cancer and viral infections.</p><p>To date, few Hsp70 inhibitors have been identified and characterized, and their efficacy in clinical settings is unknown. Through the fluorescence-linked enzyme chemoproteomic strategy (FLECS) screen, an allosteric inhibitor selective for Hsp70i was identified, called HS-72. We show that HS-72 is highly selective for Hsp70i, over the broader purinome and other Hsp70 family members, in particular the closely related constitutively active Hsp70 family member, Hsc70. Additionally, HS-72 acts as an allosteric inhibitor to induce a conformational change and inhibit Hsp70i activity. HS-72 displays hallmarks of Hsp70i inhibition in vitro by promoting Hsp70i substrate protein degradation, protein aggregation, and selective growth inhibition of cancer cells. In wild type mice HS-72 is well tolerated and a limited PK study shows HS-72 is bioavailable. Furthermore, in a MMTV-neu breast cancer mouse model, HS-72 shows efficacy to inhibit tumor growth and promote survival.</p><p>Due to the similar utilization of Hsp70i in cancer and viral pathogenesis, this suggests the potential for HS-72 as an antiviral agent. Dengue virus (DENV) is of great public health importance due to estimates of up to 400 million infections per year, coupled with the geographic distribution of the virus, which is now endemic in over 100 countries worldwide. There is also a pressing need for DENV interventions, owing to the lack of approved vaccines or antiviral therapies. DENV is reliant on host factors throughout the viral life cycle and Hsp70i has been implicated as a host factor in DENV pathogenesis. Additionally, the complete role of Hsp70i in DENV pathogenesis remains to be elucidated, highlighting a unique opportunity to use HS-72 as a tool to specifically probe Hsp70i function. In monocytes, Hsp70i is expressed at low levels preceding DENV infection, but Hsp70i expression is induced upon DENV infection. Furthermore, inducing Hsp70i expression prior to infection, correlates with an increase in DENV infection. Targeting Hsp70i with HS-72, results in a dose dependent reduction in DENV infected monocytes, while cell viability was maintained, through inhibiting the entry stage of the viral life cycle. Following infection, Hsp70i localizes to the cell surface and interacts with the DENV receptor complex to mediate viral entry. While, HS-72 treatment results in a disruption of the interaction of Hsp70i with the DENV receptor complex, yielding a reduction in infected cells. </p><p>Collectively this work further supports Hsp70i as an anticancer and anti-dengue virus target, and identifies HS-72, a chemical scaffold that is amenable to resynthesis and iteration, as an ideal starting point for a new generation of therapeutics targeting Hsp70i.</p> / Dissertation Pharmacology Molecular biology Cancer Dengue Virus Heat Shock Protein 70 Small Molecule
76	The Discovery and Characterization of NAD-Linked RNA Chen, Ye Grace 21 June 2014 (has links) Over the past few decades, RNA has emerged as much more than just an intermediary in biology’s central dogma. RNA is now known to play a variety of catalytic, regulatory and defensive roles in living systems as demonstrated through the discoveries of ribozymes, riboswitches, microRNAs, small interfering RNAs, Piwi-interacting RNAs, small nuclear RNAs, clusters of regularly interspaced short palindromic repeat RNAs and long non-coding RNAs. In contrast to the functional diversity of RNA, the chemical diversity has remained primarily limited to canonical polyribonucleotides, the 5’ cap on mRNAs in eukaryotes, modified nucleotides and 3’-aminoacylated tRNAs. This disparity coupled with the powerful functional properties of small molecule-nucleic acid conjugates led us to speculate that novel small molecule-RNA conjugates existed in modern cells, either as evolutionary fossils or as RNAs whose functions are enabled by the small molecule moieties. We developed and applied a nuclease-based screen coupled with high-resolution liquid chromatography/mass spectrometry analysis to detect novel small molecule-RNA conjugates, broadly and sensitively. We discovered NAD-linked RNA in two types of bacteria and further characterized the small molecule and RNA in Escherichia coli. The NAD modification is found on the 5’ end of RNAs between 30 and 120 nucleotides long, and is surprisingly abundant at around 3,000 copies per cell. Subsequent experiments to characterize further NAD-linked RNA have been undertaken, including sequencing the RNAs to which NAD is attached and elucidating the biological functions of the small molecule-RNA conjugate. The development and application of a screen to detect novel nucleotide modifications that is independent of structure or biological context has the potential to increase our understanding of the functional and chemical diversity of RNA. The discovery and biological characterization of NAD-linked RNA can provide new examples of RNA biology and offer insight into the RNA world. bacteria NAD RNA modifications small molecule-RNA conjugates molecular biology chemistry
77	Modulators of Cellular and Biochemical PRC2 Activity Paulk, Joshiawa Lanair James 21 October 2014 (has links) EZH2 is a SET domain-containing methyltransferase and the catalytic component of the multimeric Polycomb- group (PcG) protein complex, PRC2. When in complex with other PRC2 members (EED, SUZ12, AEBP2, and RBBP4), EZH2 catalyzes methylation of H3K27, a histone modification associated with transcriptional repression and developmental regulation. As several PRC2 components are upregulated or mutated in a variety of human cancers, efforts to discover small-molecule modulators of PRC2 and understand its regulation may yield therapeutic insights. Identification of small-molecule probes with distinct chemotypes, MOAs, and selectivity profiles are not only of great value, but necessary in establishing comprehensive probe sets capable of illuminating the various roles of EZH2 in oncogenesis. Here we describe efforts to identify and characterize small-molecule modulators of PRC2 and further understand its regulation. Chapter II outlines the expression and purification of 5-component PRC2 (EZH2-EED-SUZ12-AEBP2-RBBP4) and the establishment of biochemical and cellular HTS assays. These assays were used to screen a diverse set of small molecules (>120,000), identifying biochemical PRC2 inhibitors and activators (described in Chapter III). One biochemical PRC2 inhibitor, BRD1835, appeared to inhibit PRC2 activity through a novel artifactual mechanism involving interaction with peptide substrate, leading to apparent peptide-competitive behavior and putative cellular activity (described in Chapter IV). The characterization of novel biochemical PRC2 activators, BRD3934 and BRD8284, is discussed in Chapter V. Chapter VI describes the use of an HCS assay to identify known bioactive compounds that alter intracellular levels of H3K27me3 through modulating H3K27me3-connected regulatory nodes or by targeting PRC2 directly. These efforts led to the discovery that an antifungal agent, miconazole, is capable of activating PRC2 activity in vitro, while a mucolytic agent, bromhexine, selectively ablates cellular H3K27me3 levels through targeting an activity distinct from PRC2. Finally, Chapter VII discusses novel PRC2-connected crosstalk mechanisms identified through screening libraries of uniquely modified histone peptides for their ability to bind or support methylation by PRC2. These studies enhance our understanding of PRC2 regulation by revealing the effects of H3R26 and H3K23me1 modifications on enzymatic activity, implicating their respective methyltransferases in PRC2 regulation. Biochemistry Chromatin EZH2 High-throughput screening Histone crosstalk PRC2 Small-molecule probes
78	Regulation of constitutive platelet-derived growth factor receptor degradation by the 105 kilodalton isoform of ankyrin3 2014 March 1900 (has links) Deregulation of platelet-derived growth factor receptor (PDGFR) signaling is a driving event in glioblastoma, promotes tumor progression epithelial to mesenchymal transition (EMT) in multiple cancers, modulates the tumor stroma to facilitate tumorigenesis and reduces tumor uptake of chemotherapeutics. Previous studies identified the 105 kDa isoform of ankyrin3 (Ank105) as a binding partner of the PDGFR signaling machinery and demonstrated that expression of Ank105 promoted PDGFR degradation (Ignatiuk et al., 2006)(Ignatiuk et al., 2006)(Ignatiuk et al., 2006). Receptor tyrosine kinases are targeted for degradation via endocytosis and ubiquitin-dependent trafficking to the lysosome. It was hypothesized that Ank105 promoted the constitutive degradation of the PDGFR and attenuation of PDGFR signaling by facilitating endocytosis of the PDGFR and targeting the PDGFR for lysosomal degradation via an ubiquitin-dependent mechanism. The studies in this thesis characterized the effects of Ank105 expression on PDGFR signaling and protein expression levels, determined the endocytic pathways involved in Ank105-mediated PDGFR degradation and studied the role of ubiquitin binding in Ank105 function. The most robust effect of Ank105 expression on the PDGFR was constitutive degradation as PDGFR protein expression levels in Ank105-expressing cells were significantly reduced compared to NIH 3T3 cells in the absence of PDGF ligand. Low constitutive PDGFR levels resulted in attenuated pro-proliferative AKT and mitogen-activated protein kinase (MAPK) signaling in response to ligand stimulation. To determine the endocytic requirements for Ank105-mediated constitutive PDGFR degradation, a constitutive PDGFR degradation assay was developed and the effects of several small molecule endocytosis inhibitors were evaluated. Additionally, the small molecule endocytosis inhibitors were validated by determining the effects of these inhibitors on low density lipoprotein (LDL) uptake and ligand-induced PDGFR degradation in Ank105-expressing cells. Both LDL uptake and ligand induced PDGFR degradation are known to proceed by a clathrin and dynamin dependent mechanism of endocytosis. In Ank105-expressing cells, both LDL uptake and ligand incuded PDGFR degradation were dependent upon clathrin and dynamin function. Interestingly, constitutive PDGFR degradation in Ank105-expressing cells was not dependent upon CME, but required dynamin activity. Expression of Ank105 may promote clathrin-independent, dynamin-dependent, constitutive endocytosis of the PDGFR. Additionally, acute inhibition of either lysosomal or proteasomal degradation strongly impaired constitutive PDGFR degradation, whereas ligand-induced PDGFR degradation was less sensitive to protein degradation inhibitors, while LDL uptake was unaffected. It was unclear if PDGFR was degraded in the proteasome or if the proteasome was involved in sorting of PDGFR to the lysosome for degradation. Ubiquitination of receptors is required to target them for degradation. Ank105 was assayed for the ability to interact with ubiquitin and ubiquitinated proteins. Interestingly, Ank105 bound ubiquitin in vitro via the spectrin binding domain and co-immunoprecipitated with several ubiquitinated proteins, suggesting a role for Ank105 in the sorting of ubiquitinated proteins for degradation. Furthermore, Ank105 co-immunoprecipitated with a number of high and low molecular weight proteins in the absence of PDGF stimulation. Identification of Ank105 binding partners would provide further insight in the mechanism of Ank105-mediated constitutive PDGFR degradation. In summary, Ank105 promoted the attenuation of PDGFR signaling via alteration of constitutive PDGFR endocytosis and targeting of constitutive PDGFR for degradation, potentially through interaction with ubiquitin and ubiquitinated proteins. Reduction of constitutive PDGFR levels in cancers with PDGFR driver mutations, acquired PDGF responsiveness and stromal expression of PDGFR, could significantly reduce tumor proliferation, tumorigenesis and increase effectiveness of chemotherapeutics.
79	Targeting Pleckstrin Homology Domains for the Inhibition of Cancer Growth and Metastasis Moses, Sylvestor Andrea January 2013 (has links) Pleckstrin homology (PH) domains are structurally conserved domains, which generally bind to phosphatidylinositol phosphate (PtdInsP) lipids. They are present in a variety of proteins, including those that are upregulated in cancer growth and metastasis, and represent a crucial component of intracellular signaling cascades and membrane translocation. Thus, they may be considered as attractive targets for cancer drug therapy. AKT (protein kinase B), a pleckstrin homology lipid binding domain and a serine/threonine kinase-containing protein, is a key component of the phophatidylinositol-3-kinase (PI3K)/AKT cell survival signaling pathway which is activated in a variety of cancers, including prostate, pancreatic, and skin cancers. In this study, I report the finding of a novel inhibitor of AKT; PH-427. I describe its effects on binding to the PH domain of AKT thus preventing its binding to PtdIns3-P at the plasma membrane and subsequent activation. In vivo testing of the drug led to reduction of tumor size and numbers in a mouse pancreatic cancer model. Additional testing of PH-427 on squamous cell carcinomas revealed that the drug is able to reduce tumor burden and multiplicity in vivo when topically applied. Thus, we demonstrate proof-of-principle in targeting PH domains as a viable cancer drug therapy option. The effects of PH-427 raised the intriguing possibility that targeting PH domains may have beneficial effects in other signaling pathways with PH domain-containing proteins. Guanine exchange factors (GEFs) contain a Dbl homology (DH) domain and a PH domain and have been shown to be involved in the process of metastasis. More specifically, RacGEFs activate Rac1 GTPase by facilitating the exchange of GDP to GTP. Over-expression of certain GEFs has been shown to contribute to increased malignancy in a variety of cancers. T-lymphoma invasion and metastasis-inducing protein-1 (Tiam1) is a highly conserved GEF and contains an N-terminal pleckstrin homology domain (nPH) and a DH/C-terminal PH domain (cPH). Tiam1 has been found to be over-expressed in several cancers, including breast, colon and prostate cancers. In this study, I describe the identification, development, experimental testing, and potential mechanism of action of novel small molecule inhibitors targeting the RacGEF Tiam1 to inhibit prostate cancer bone metastasis. Drug Discovery Metastasis Pleckstrin Homology Domains Small Molecule Inhibitors Tiam1 Molecular & Cellular Biology Akt
80	Disruption of Transforming Growth Factor-beta Signaling Using a Small Molecule TGF-beta Receptor Type I Kinase Inhibitor Improves the Efficacy of Dendritic Cell Vaccines Rausch, Matthew Peter January 2008 (has links) Immunotherapy has been proposed as an alternative to conventional cancer therapies due to its reduced toxicity and ability to induce long-lasting anti-tumor immune responses. Dendritic cell (DC) vaccination is one immune-based anti-cancer strategy that has received attention due to the ability of DC to process and present antigen to T lymphocytes to initiate immune responses. However, the clinical efficacy of DC-based immunotherapy against established cancers in humans has been extremely low and despite recent advances, objective response rates in DC vaccine trials are rarely above 10%. This lack of efficacy is due in part to immunosuppressive factors, such as transforming growth factor &beta (TGF-&beta), present in the tumor microenvironment that promote tumor immune escape. Therefore, TGF-&beta represents a major barrier to effective cancer immunotherapy and strategies to neutralize this cytokine may lead to more efficacious DC vaccines.In this study, we employed two small molecule transforming growth factor &beta receptor type I (T&betaRI/ALK5) kinase inhibitors (HTS466284 and SM16) in combination with DC vaccines to treat established TGF-&beta-secreting 4T1 mammary tumors. The results demonstrate that while both inhibitors blocked the effects of TGF-&beta in vitro, HTS466284 by itself or in combination with DC vaccination was unable to consistently control the growth and metastasis of established 4T1 tumors. In contrast, SM16 inhibited the growth of established tumors when delivered orally and suppressed the formation of pulmonary metastases when delivered orally or via daily intraperitoneal (i.p.) injection. The efficacy of SM16 was dependent on cellular immunity as this drug had no effect in immunodeficient SCID mice. Furthermore, orally delivered SM16 in combination with DC vaccination led to complete tumor regression in several mice that correlated with increased T cell infiltration of the primary tumor and enhanced in vitro IFN-gamma production and tumor-specific cytolytic activity by splenocytes. Finally, a suboptimal dose of SM16 that failed to control primary tumor growth on its own synergized with DC vaccination to inhibit the growth of established 4T1 tumors. These findings suggest that blockade of TGF-&beta signaling using a small molecule T&betaRI/ALK5 kinase antagonist may be an effective strategy to bolster the efficacy of DC-based cancer vaccines. Breast Cancer Dendritic Cell Immunotherapy Small Molecule Kinase Inhibitor Transforming Growth Factor Beta

Search results