Mass spectrometric analysis of monolayer protected nanoparticles

Zhu, Zhengjiang

01 January 2012

Monolayer protected nanoparticles (NPs) include an inorganic core and a monolayer of organic ligands. The wide variety of core materials and the tunable surface monolayers make NPs promising materials for numerous applications. Concerns related to unforeseen human health and environmental impacts of NPs have also been raised. In this thesis, new analytical methods based on mass spectrometry are developed to understand the fate, transport, and biodistributions of NPs in the complex biological systems. A laser desorption/ionization mass spectrometry (LDI-MS) method has been developed to characterize the monolayers on NP surface. LDI-MS allows multiple NPs taken up by cells to be measured and quantified in a multiplexed fashion. The correlations between surface properties of NPs and cellular uptake have also been explored. LDI-MS is further coupled with inductively coupled plasma mass spectrometry (ICP-MS) to quantitatively measure monolayer stability of gold NPs (AuNPs) and quantum dots (QDs), respectively, in live cells. This label-free approach allows correlating monolayer structure and particle size with NP stability in various cellular environments. Finally, uptake, distribution, accumulation, and excretion of NPs in higher order organisms, such as fish and plants, have been investigated to understand the environmental impact of nanomaterials. The results indicate that surface chemistry is a primary determinant. NPs with hydrophilic surfaces are substantially less toxic and present a lower degree of bioaccumulation, making these nanomaterials attractive for sustainable nanotechnology.

Organic materials as templates for the formation of mesoporous inorganic materials and ordered inorganic nanocomposites

Ziegler, Christopher R

01 January 2011

Hierarchically structured inorganic materials are everywhere in nature. From unicellular aquatic algae such as diatoms to the bones and/or cartilage that comprise the skeletal systems of vertebrates. Complex mechanisms involving site-specific chemistries and precision kinetics are responsible for the formation of such structures. In the synthetic realm, reproduction of even the most basic hierarchical structure effortlessly produced in nature is difficult. However, through the utilization of self-assembling structures or "templates", such as polymers or amphiphilic surfactants, combined with some favorable interaction between a chosen inorganic, the potential exists to imprint an inorganic material with a morphology dictated via synthetic molecular self-assembly. In doing so, a very basic hierarchical structure is formed on the angstrom and nanometer scales. The work presented herein utilizes the self-assembly of either surfactants or block copolymers with the desired inorganic or inorganic precursor to form templated inorganic structures. Specifically, mesoporous silica spheres and copolymer directed calcium phosphate-polymer composites were formed through the co-assembly of an organic template and a precursor to form the desired mesostructured inorganic. For the case of the mesoporous silica spheres, a silica precursor was mixed with cetyltrimethylammonium bromide and cysteamine, a highly effective biomimetic catalyst for the conversion of alkoxysilanes to silica. Through charge-based interactions between anionic silica species and the micelle-forming cationic surfactant, ordered silica structures resulted. The incorporation of a novel, effective catalyst was found to form highly condensed silica spheres for potential application as catalyst supports or an encapsulation media. Ordered calcium phosphate-polymer composites were formed using two routes. Both routes take advantage of hydrogen bonding and ionic interactions between the calcium and phosphate precursors and the self-assembling copolymer template. Some evidence suggests that the copolymer morphology remained in the composite despite the known tendency for calcium phosphates to form highly elongated crystalline structures with time, as is commonly the case for synthetic hydroxyapatites. Such materials have obvious application as bone grafts and bone coatings due, in part, to the osteoconductive nature of calcium phosphate as well as to the mesoporosity generated through the cooperative assembly of the block copolymer and the inorganic. Future work, including potential experiments to determine osteoconductivity of as-prepared composites, is also presented herein.

A change in structure meaningful learning and cognitive development in a spiral, organic chemistry curriculum /

Grove, Nathaniel P.

January 2008

Thesis (Ph. D.)--Miami University, Dept. of Chemistry and Biochemistry, 2008. / Title from first page of PDF document. Includes bibliographical references (p. 121-127).

Discovery of epigenetic probes against the bromodomain family of proteins

Clark, Peter George Keith

January 2015

Chemical probes are necessary for elucidating the biochemical roles of proteins. Bromodomains are protein-interaction modules found in a family of proteins implicated in the epigenetic regulation of transcription; however, the individual roles remain unknown for many bromodomain proteins, without potent and selective ligands available to assist in their study. From lead compounds, a structure-based drug discovery program was to be explored with the use of biophysical assays and appropriate chemical methods to expediate development of probes against a number of these proteins. A fragment lead against BRD4 was developed into PNZ5, a potent (K_D 5 nM) BRD4 probe with a high ligand efficiency. Although enantioselective syntheses and the use of an alternative synthetic route were unsuccessful, PNZ5 showed cytotoxic activity against gastric cancer cell lines that had proved resilient to existing anticancer agents. Optimisation of a lead compound against BRD9 resulted in the development of LP99, the first reported BRD7/9 probe, that was potent (BRD9 K_D 99 nM, BRD7 K_D 909 nM), selective amongst bromodomain proteins and active in cells. An enantioselective synthesis was performed using chiral organocatalyts and LP99 was used to identify a previously unknown role of BRD7/9 in the regulation of inflammatory processes. Research is ongoing to assess further biochemical roles of these proteins with LP99. Arising from a more potent lead against BRD9, a series of structurally related compounds were synthesised to explore SAR around this ligand, however no improvement on the affinity of the lead was realised. Finally, based on disclosed lead structures against PCAF, a series of compounds were synthesised to replicate their activity. A number of important binding interactions were assessed and a lead structure was identified (K_D 1 μM). Development is ongoing to progress this lead into the first reported PCAF probe.

572

Studies towards the chemical origins of life

Islam, Saidul

January 2011

The 'RNA World' hypothesis states that RNA was the first living system on the primitive Earth, where it carried out dual genotypic and phenotypic functions. Therefore, RNA must have self-assembled by purely chemical means from small prebiotic feedstock molecules. A plausible demonstration of the synthesis of RNA with the natural [5'→3'] phosphodiester linkage, and its self-replication has not been achieved so far. Some have speculated a 'simpler' informational polymer preceded it, and biology based on this polymer subsequently 'invented' RNA. The structurally simpler L-α-threofuranosyl nucleic acid (TNA) has been proposed as a primordial ancestor to RNA. A study into the potential self-assembly of TNA nucleotides was carried out. It is shown that as a direct result of TNA's structural simplicity, its generational chemistry is more difficult than RNA. The tetrose aminooxazolines are unstable under the conditions of its formation. The tetrose anhydronucleosides efficiently incorporate phosphate to form activated tetrose cytidine-2',3'-cyclic phosphates, but with the wrong stereochemistry. Strong support for the 'RNA world' hypothesis came from a report in 2009 of the prebiotic synthesis of activated pyridimine ribonucleoside-2',3'-cyclic phosphates. Oligomerisation studies were carried out on these activated monomers with various catalysts, and NMR studies were carried out to determine the aspects of their reactivity. It was found that only short oligomers are formed. However, nucleoside-2',3'-cyclic phosphates were found to selectively hydrolyse to a 2:1 mixture of 3' and 2'-monophosphates, and this observation was considered as etiologically relevant. Nucleoside-2' and 3'-monophosphates cyclise back to nucleoside-2',3'-cyclic phosphates upon phosphate activation, and so cannot be considered as direct candidates for oligomerisation. A chemistry that selectively uses the nucleoside-3'-phosphate for the synthesis of RNA, and recycles the unwanted 2'-phosphate would be highly desirable. Thus, a regio- and chemoselective reaction that selectively acetylates monomer and oligomer nucleoside-3'-phosphates at the 2'-hydroxyl in water is presented. Nucleoside-2'-phosphates are shown to acetylate less efficiently, and show a greater propensity to recyclise back to nucleoside-2',3'-cyclic phosphates. Purine nucleotides were also found to acetylate better than pyrimidines. This potentially primordial protecting group chemistry approach towards the prebiotic synthesis of RNA is conceptually novel, and has the potential to give a natural [5'→3'] phosphodiester linkage isomer. It is considered as a major step towards solving the long-standing problem of non-enzymatic self-replication of RNA.

570

Synthesis of Benzimidazolone Glucose Uptake Inhibitors

Duffner, Jack Patrick

29 June 2018

No description available.

Organic Chemistry

Chemistry

The synthesis and biology of iminosugars and their precursors

Ayers, Benjamin James

January 2014

Iminosugars are carbohydrate mimics, where the endocyclic ring oxygen has been replaced by nitrogen. This substitution affords these compounds their inhibitory activity towards sugar-processing enzymes (glycosidases) and, as a consequence, their chemotherapeutic potential in the treatment of a broad range of diseases. Several iminosugars are currently in clinical trials or have entered the market as approved drugs. This has consequently led to increasing levels of research into their synthesis and application, both in terms of the development of efficient methodology to access naturally occurring examples, and also to elaborate novel scaffolds. The presence of multiple chiral centres within iminosugars provides a considerable challenge in accessing these targets by asymmetric means, whereas carbohydrates pose a more attractive chiral pool. As such the majority of literature methods have employed this latter method. The focus of the thesis is on the elaboration of robust methodologies to access both naturally occurring and novel iminosugars, and their precursors, from readily available carbohydrate starting materials. Chapter 1 presents an introduction to iminosugars, including an overview of glycosidase inhibition by this class of sugar-mimic, their historical medical usage and the basis for their potential employment in treating diabetes, lysosomal storage disorders (LSDs) and cancer. This chapter also gives a general review of the methods employed in the literature for the assembly of iminosugar scaffolds. Chapter 2 is concerned with the synthesis of iminosugars from the carbohydrate glucuronolactone. This versatile chiron has previously allowed for access to many homochiral targets, and in this thesis is used to access DGJNAc on a gram-scale. This iminosugar has been shown to be a potent α-N-acetylgalactosaminidase inhibitor and is potentially extremely valuable in the treatment of late-stage cancer. Both enantiomers of glucuronolactone are also utilised in the divergent synthesis of every stereoisomer of two classes of five-membered iminosugars; the pyrrolidines (including DMDP), and the proline amides. These compounds demonstrate remarkable biological activity against a panel of glycosidases and hexosaminidases, allowing for the analysis of the structure-activity relationship between these compounds and the target enzymes. Chapter 3 describes the development of a novel, one-pot methodology - a tandem Strecker reaction and iminocyclisation - for the assembly of trihydroxy piperidine α-iminonitriles from a range of unbranched and branched pentose monosaccharides. These piperidine α-iminonitriles are precursors to pipecolic acids which may also be potentially valuable targets in the treatment of cancer.

547

Chemical tools for the study of epigenetic mechanisms

Lercher, Lukas A.

January 2014

The overall goal of my work was to develop and apply new chemical methods for the study of epigenetic DNA and protein modifications. In Chapter 3 the development of Suzuki-Miyaura cross coupling (SMcc) for the post-synthetic modification of DNA is described. DNA modification by SMcc is efficient (4-6h) and proceeds under mild conditions (37°C, pH 8.5). The incorporation of various groups useful for biological investigations is demonstrated using this methodology. Using a photocrosslinker, introduced into the DNA by SMcc capture experiments are performed to identify potential binding partners of modified DNA. In Chapter 4 a dehydroalanine (Dha) based chemical protein modification method is described that enables the introduction of posttranslational modification (PTM) mimics into histones. The PTM mimics introduced by this method are tested using western- and dot-blot and binding and enzymatic assays, confirming they function as mimics of the natural modifications. Chapter 5 describes the use of a generated PTM mimics to elucidate the function of O-linked β-Nacetylglucosamine (GlcNAc) of histones in transcriptional regulation. It is shown that GlcNAcylation of Thr-101 on histone H2A can destabilize nucleosome by modulating the H2A/B dimer – H3/H4 tetramer interface. N- and C-terminal histone tails play an important role in transcriptional regulation. In Chapter 6, nuclear magnetic resonance is used to investigate the structure of the histone H3 N-terminal tail in a nucleosome. The H3 tail, while intrinsically disordered, gains some α-helical character and adopts a compact conformation in a nucleosome context. This H3 tail structure is shown to be modulated by Ser-10 phosphorylation. The effect of a new covalent DNA modification, 5- hydroxymethylcytosine (5hmC), on transcription factor binding is investigated in Chapter 7. 5hmC influences HIF1α/β, USF and MAX binding to their native recognition sequence, implying involvement of this modification in epigenetic regulation.

572.8

Halogen bonding interlocked host systems for recognition and sensing of anions

Mullaney, Benjamin R.

January 2014

This thesis describes the synthesis of halogen bonding receptors for integration within interlocked anion host systems. Chapter 1 introduces the field of supramolecular chemistry, with a particular focus on anion recognition and sensing, halogen bonding, and the synthesis of mechanically interlocked structures. Chapter 2 describes the preparation and anion binding properties of carbazole-based receptor molecules. A systematic anion binding study on a series of halogen- and hydrogen-bonding 3,6-bis-triazolium carbazole acyclic receptors is described initially, followed by the development of a halogen bonding rotaxane. The anion and metal complexation properties of acyclic and macrocyclic systems incorporating the 1,8-bis-triazole carbazole motif are also presented. Chapter 3 details the synthesis and anion complexation investigations of halogen and hydrogen bonding naphthalene-based acyclic and interlocked rotaxane host molecules. Chapter 4 presents receptors based on the 4,4'-bis-triazole-2,2'-bipyridyl motif. A halogen bonding rhenium(I) bipyridyl complex is exploited in the development of a rotaxane host system which optically senses anions via luminescence purely through halogen bonding interactions. The anion recognition and sensing properties of diquat-based receptors are also investigated, and shown to exhibit optical and electrochemical responses to anions. Chapter 5 summarises the major conclusions from Chapters 2-4. Chapter 6 describes the experimental procedures used in the work, and includes characterisation data for the synthesised compounds. Supplementary information relating to crystallographic data, and absorption, luminescence and electrochemical studies, is provided in the Appendices.

546

The synthesis of azetidine and piperidine iminosugars from monosaccharides

Lenagh-Snow, Gabriel Matthew Jack

January 2012

Iminosugars are polyhydroxylated alkaloids, and can be generally defined as sugar mimetics in which the endocyclic oxygen atom has been replaced with a basic nitrogen. A common affect of this atomic substitution is to bestow these compounds with the ability to inhibit various sugarprocessing enzymes; most significantly the glycosidases (glycoside hydrolases) which areintimately involved in a huge array of biological functions. Compounds which inhibit these enzymes concordantly possess much potential as medicinal agents for the treatment of a variety of diseases. Several iminosugars have already achieved market approval as drugs, and many more are promising candidates in the late stages of clinical development. As such there remains considerable interest in this class of compound, both in terms of the exploration of novel iminosugar structures, as well as the continual development of more efficient general methodology for their synthesis. The densely-packed functionality and stereochemical information present in iminosugars makes them challenging targets for asymmetric chemical synthesis, whereas carbohydrates are clearly very attractive as chiral-pool starting materials for this purpose. Indeed, the majority of the most successful syntheses of iminosugars use the latter approach, and such is the focus of this thesis. Chapter 1 presents a relatively brief introduction to iminosugars, including their types of structure, natural occurrence and biological mode of action. The rationale behind their use as therapeutic agents for the treatment of some significant disease targets is also discussed. Chapter 2 is concerned with the preparation of a number of novel polyhydroxylated azetidines, and their evaluation as glycosidase inhibitors. Such compounds represent an almost entirely neglected class of iminosugars within the literature. An overview of natural and synthetic products incorporating an azetidine motif is given, as well as a brief review of preparative methods and known azetidine iminosugars. A highly efficient and flexible method for the key azetidine ring formation is demonstrated by the cyclisations of 3,5-di-O-triflates of pentoses and hexoses, and of a 2,4-di-O-triflate of glucose, with various primary amines. In this manner, many azetidine triols and tetrols were prepared in good yield. Furthermore, this process is readily adaptable to the installation of added functionality to the azetidine scaffold, as demonstrated by the preparation of 1-acetamido analogues. The initial biological screening of these compounds showed a promising array of glycosidase inhibition, including that of selective inhibition of fungal enzymes. Chapter 3 describes a strategy with which to prepare all sixteen stereoisomers of a known piperidine iminosugar, alpha-homonojirimycin (alpha-HNJ), in a highly divergent manner from just four of the possible thirty-two 6-azidoheptitols using traditional chemical synthesis in tandem with biotechnological transformations. One half of the execution of this strategy is described in this thesis. Two 6-azidoheptitols were prepared from D-mannose, thereby providing access to four 6-azidoketoheptoses through a combination of microbial oxidation and enzymatic epimerisation. Catalytic hydrogenation of these 6-azidoketoheptoses furnished four diastereomeric mixtures of 2,6-iminoheptitols, with varying degrees of stereoselectivity. Purification of these mixtures allowed six 2,6-iminoheptitols to be isolated, two of which have never previously been tested for glycosidase inhibition. Significantly, one of them was found to be a potent and highly selectiveinhibitor of alpha-galactosidases, and may therefore be of interest in the treatment of Fabry disease.

547.78