Synthesis of Selective 5-HT7 Receptor Antagonists

Ehalt, Adam

18 November 2011

The 5-HT7 receptor is the most recent addition to the 5-HT receptor family and has been linked to a variety of physiological and pathophysiological processes. Well established antide-pressant pharmaceuticals have recently been found to activate the 5-HT7 receptor, supporting the role of the 5-HT7 receptor in the antidepressant mechanism. The synthesis of potent selec-tive 5-HT7 receptor antagonists could afford a greater understanding of the 5-HT7 receptor function as well as lead to potential drug candidates. The synthesis of unfused biheteroaryl derivatives as 5-HT7 receptor ligands has been de-scribed within. These compounds have been tested for biological activity on the 5-HT6 and 5-HT7 receptors. 4-(3’-Furyl)-2-(N-substituted-piperazino)pyrimidines were found to be potent 5-HT7 receptor ligands. 4-(2’-Furyl)-2-(N-substituted-piperazino)pyrimidines have shown high se-lectivity for the 5-HT7 receptor over the 5-HT6 receptor.

Serotonin

5-HT7 receptor

Organic

Heterocyclic chemistry

Synthesis

Synthesis and Biochemical Studies of a Novel Thiol Modified Nucleotide

Esmaeili, Razieh

17 December 2014

Nucleic acids are important bio-macromolecules in living systems. They are involved in important functions like gene expression and regulation. Nucleoside triphosphates serve as precursors for biochemical synthesis of modified nucleic acids and nucleotide coenzymes. The modification of nucleic acids, particularly at nucleobases, can expand the function and chemical properties of nucleic acid. Herein, we report the chemical synthesis of a novel thiol-modified nucleoside S-(3-(acetylthio)propyl)-5-(mercaptomethyl)-uridine and the corresponding nucleotide via a “new synthetic methodology” developed in our laboratory. The synthesized triphosphate was used for RNA transcription. The activity and nuclease resistance of the transcribed RNA is studied. The results showed that the properties of the nucleotide with thiol functionality are as good as the native. The modified RNA can be used for RNA/protein complex structure studies and gold nanoparticles stabilizer. They can also serve as a probe in DNA/RNA microchip surface functionalization for detection of various diseases and pathogens.

Modified nucleic acids

Nucleoside

Thiol-modification of nucleic acids

Transcription

Hammerhead ribozyme

Thiol-uridine

Nucleoside 5’-triphosphate

Synthesis and Characterization of New Near-Infrared Chromophores: Cyanine and Phenoxazine Derivatives

Soriano Juarez, Eduardo Salvador

11 August 2015

This thesis reports the synthesis of new near infrared dyes in three chapters. The first two chapters outline the synthetic procedure for synthesizing mono- and pentamethine cyanine dyes. The initial chapter encompasses the synthesis of asymmetric monomethine dyes with red-shifted optical properties. The second chapter involves the synthesis and assessment of new symmetrical quinolin-4-yl and phenanthridin-6-yl pentamethine dyes as potential oxidative DNA cleavage agents. The last chapter of the thesis details the synthesis and evaluation of new phenoxizinum dyes as contrast agents for insulunomia, a pancreatic cancer. Furthermore, all new compounds were characterized via NMR and their coherent optical properties were obtained.

Synthesis of Aza-Heterocyclic Monoamidines as Potential DNA Minor Groove Binders, Anti-Trypanosomals, and Boron Neutron Capture Therapy Agents

Green, Julius

17 December 2014

A series of combilexin-like monoamidines has been synthesized by linking an intercalative unit with the DNA minor groove binder DB 818 via “Click chemistry.” DB 818 is a dicationic minor groove binder that has shown strong binding affinity to AT sequences. The aim was to synthesize novel classes of DNA minor groove binders that are combilexin-like – minor groove binder / intercalator hybrid – as potential unique DNA binding agents and therapeutics against African Sleeping Sickness. Additionally, a series of novel benzo[d]1,3,2-diazaboroles DAPI derivatives were also synthesized and investigated. These boron compounds have the potential to be strong DNA minor groove binders because of their lower pKa and act as potential chromophores for Boron Neutron Capture Therapy.

Combilexin

Diazaborole

DNA minor groove binder

African Sleeping Sickness

SYNTHESIS OF AZA-HETEROCYCLIC MONOAMIDINES AS POTENTIAL DNA MINOR

Green, Julius

17 December 2014

A series of combilexin-like monoamidines has been synthesized by linking an intercalative unit with the DNA minor groove binder DB 818 via “Click chemistry.” DB 818 is a dicationic minor groove binder that has shown strong binding affinity to AT sequences. The aim was to synthesize novel classes of DNA minor groove binders that are combilexin-like – minor groove binder / intercalator hybrid – as potential unique DNA binding agents and therapeutics against African Sleeping Sickness. Additionally, a series of novel benzo[d]1,3,2-diazaboroles DAPI derivatives were also synthesized and investigated. These boron compounds ave the potential to be strong DNA minor groove binders because of their lower pKa and act as potential chromophores for Boron Neutron Capture Therapy.

Combilexin

Diazaborole

DNA minor groove binder

African Sleeping Sickness

Heme-dependent Tryptophan Oxidation: Mechanistic Studies on Tryptophan 2,3-Dioxygenase and MauG

Geng, Jiafeng

17 December 2014

Hemoenzymes are prevalent in nature and participate in a wide range of biological activities. Frequently, high-valence iron intermediates are involved in the catalytic events of these enzymes, especially when the activation of peroxide or dioxygen is involved. Building on the fundamental framework of iron-oxygen chemistry, the mechanistic understandings of these enzymes and their reactive intermediates constantly attract attention from the enzymology community. This dissertation work focused on the mechanistic studies on two hemoenzymes, tryptophan 2,3-dioxygenase (TDO) and MauG, both of which catalyze unique chemical transformations, i.e., tryptophan oxidation. TDO and MauG are structurally distinct from each other; they catalyze different types of oxidization reactions on tryptophan via diverse strategies. TDO catalyzes the ring-cleavage dioxygenation reaction of free L-tryptophan, incorporating both oxygen atoms from dioxygen into the substrate. MauG uses hydrogen peroxide as the oxidant to catalyze a complex posttranslational-modification reaction on two tryptophan residues from a protein substrate. It utilizes radical chemistry to perform a 40-Å long-range catalytic event. Despite the differences in their catalytic behavior, both enzymes are suggested to employ high-valence iron intermediates in their reactions. A collection of biochemical and spectroscopic approaches was employed to obtain detailed insight into the electronic and structural contributions to the formation and stabilization of high-valence iron intermediates, and into the heme-dependent tryptophan-oxidizing mechanisms. In the study TDO, we solved the long-standing mystery of how the active Fe(II) enzyme is generated from the resting Fe(III) form by hydrogen peroxide. A peroxide-driven reactivation mechanism was established based on the identification of a compound ES-type ferryl intermediate. Additional efforts were dedicated to clarify the controversy in the literature regarding the catalytic roles of a distal histidine residue. Chemical-rescue approaches were used to specify the catalytic contributions of the target residue. In the study of MauG, we discovered an unprecedented tryptophan-mediated charge-resonance phenomenon in the bis-Fe(IV) redox state. This discovery provides the molecular basis for the chemical reactivity and stability of the catalytically competent bis-Fe(IV) intermediate. Together with our collaborators, we also outlined the mechanism of the MauG-mediated long-range catalysis by identifying the catalytic functions of several important residues along the reaction pathway.

High-valence iron

Chemical rescue

Radical enzymology

Electron transfer

Charge resonance

Long-range catalysis

From "Click" to "Click and Release", Using Inverse Electron Demand Diels-Alder Reaction for Chemical and Medicinal Applications

Wang, Danzhu

12 August 2014

Substituted tetrazines have been found to undergo facile inversed electron demand Diels-Alder reactions with “tunable” reaction rates. By varying the substituents on tetrazine, cycloaddition rate variations of over 200 fold have been achieved with the same dienophile. Coupled with the availability of different dienophiles, such as norbornene, the reaction rate difference can be over 14,000 folds. These substituted tetrazines can be very useful for selective labeling under different conditions. This finding paves the way to utilize tetrazine conjugation reactions for not only DNA but also stage labeling work. Carbon monoxide (CO) belongs to the gasotransmitter family of signalling molecules in the mammalian systems with importance on par with that of NO and H2S. Studies have shown that endogenous production of CO has anti-inflammatory, anti-proliferative, and anti-apoptotic effects in mammalian system. Besides of the conventional metal-based carbon monoxide releasing molecules (CORMs) to deliver CO for therapeutic purposes, organic CO prodrugs represent a new direction. Here we report the “click and release” approached to release CO. Unlike the metal-based CORMs, our system does not contain transition metal and liberates CO with controllable manner and possesses potential tunable releasing rate property under physiological conditions.

Tetrazine

Click chemistry

Click and release

Carbon monoxide

CORMs

Inflammatory bowel disease

Design and Synthesis of Small-molecule Inhibitors of the Hypoxia Inducible Factor-1 as Anticancer Therapeutics

De Los Santos, Zeus Allen O.

12 August 2014

Throughout history, cancer has been severely plaguing mankind; the search for a cure to cancer had long been sought by scientists and still poses as one of the greatest challenges scientists have yet to overcome. Hypoxia in cells is a condition where there is little to no oxygen availability in its environment. In general, this event is detrimental since this can lead to cell necrosis or reoxygenation injuries. However, hypoxia, a prominent property of most solid tumors, activates the hypoxia-inducible factor (HIF-1) family of transcription factors that promotes angiogenesis. In this study, we describe the design and synthesis of small-molecule inhibitors of the HIF-1 pathway.

Hypoxia

HIF-1

Cancer

Small-molecule inhibitors

Targeting Holliday Junctions

Hamilton, Christopher

12 August 2014

Holliday junctions are formed as an intermediate during DNA recombination as the two strands come together. Recombination occurs during meiosis, and also during DNA double strand repair. Trapping this branched intermediate could prevent DNA repair from occurring in cells which would prove beneficial during cancer treatment. There are many enzymes that cleave Holliday junctions. One such enzyme, T7 Endonuclease I, was specifically chosen to detect ligand binding at the core of the junction since its binding and cleavage of cruciforms is well documented. Specialized bifunctional ligands were studied in this project that were designed to bind DNA structures that are held in close proximity to one another. These compounds have two identical binding modules that are connected by a linker of various length and rigidity, with each module binding very weakly; however, when both modules bind the binding affinity is greatly enhanced. The interactions of these compounds with cruciforms are currently being studied.

Cruciform binding ligand

Holliday junction

Homologous recombination

Optimization of Thiolate Stabilized Gold Nanoclusters For Near Infrared Emission in Subcellular Imaging

Conroy, Cecil Vincent

12 August 2014

Monothiolate protected gold nanoclusters with near IR luminescence underwent a five-to-ten fold enhancement of quantum efficiency by heating in the presence of excess thiols. Two monothiolate nanoclusters, mercaptosuccinic acid and tiopronin, were shown to benefit from this procedure. Emission maximum around 700-900 nm is favorable for bioimaging applications due to reduction of background signal from autofluorescence. Dithiolate lipoic acid protected gold nanoclusters with higher near IR quantum efficiency present an interesting candidate for biological imaging due to the difference in hydrophobicity, resistance to quenching by divalent cations and cell growth media, and retained quantum efficiency when coupled to agents such as polyethylene glycol. Intracellular and nuclear internalization of mercaptosuccinic gold nanoclusters demonstrate a potential vector for delivery of nuclear targeting agents. The small size, chemical stability, high luminescence, and potential for targeting various intracellular domains make gold nanoclusters worthwhile for further studies as potential bioimaging probes.

Gold nanoclusters

Thiol

Near-IR luminescence

Confocal imaging