Small Molecule Approaches Toward Therapeutics for Alzheimer's Disease and Colon Cancer

Smith, Breland Elise

January 2014

The research described in this dissertation is focused on the knowledge-based, often in silico assisted design, targeted synthesis, and biological evaluation of small molecules of interest for two translational medicinal chemistry projects. The first project (Part 1) is aimed at the identification of blood brain barrier (BBB) penetrable dual specificity tyrosine phosphorylation regulated kinase-1A (DYRK1A) inhibitors as a potential disease modifying approach to mitigate cognitive deficits associated with Alzheimer's neurodegeneration. Two major series with potent activity against DYRK1A were identified in addition to a number of other chemotype sub-series that also exhibit somewhat promising activity. Extensive profiling of active analogs revealed interesting biological activity and selectivity, which led to the identification of two analogs for in vivo studies and revealed new opportunities for further investigation into other kinase targets implicated in neurodegeneration and polypharmacological approaches. The second project (Part 2) is focused on the development of compounds that inhibit PGE₂ production, while not affecting cyclooxygenase (COX) activity, as a novel approach to treat cancer. Compounds were designed with the intention of inhibiting microsomal prostaglandin E₂ synthase-1 (mPGES-1); however, biological evaluation revealed phenotypically active compounds in a cell based assay with an unknown mechanism of action. Further profiling revealed promising anticancer activity in xenograft mouse models. In addition, PGE₂ has been implicated in an immune evasion mechanism of F. tularensis, a strain of bacteria that remains an exploitable threat in biowarfare, thus a small number of analogs were evaluated in a cell model of F. tularensis infection stimulated PGE₂ production.

Medicinal Chemistry

Structure Based Drug Design

Biochemistry

Drug Discovery and Development

Strukturella och funktionella studier av fyra enzymer involverade i cellväggsbiosyntes hos Mycobacterium tuberculosis / Structural and functional studies of four enzymes involved in Mycobacterium tuberculosis cell wall biosynthesis

Källgren, Joanna

January 2015

The pathogenic bacterium Mycobacterium tuberculosis (Mt) is the causative agent of tuberculosis, a widespread and fatal infectious disease. Today, treatment against tuberculosis involves a combination of drugs, which need to be taken for at least six months and which often causes severe side effects. Therefore, new drugs that are more effective and that give fewer side effects are needed. A characteristic feature of the Mt bacterium is its very complex and thick cell wall, which prevents many potential drug molecules from penetrating it. Inhibiting any one of the enzymes that are involved in its biosynthesis would therefore seem to be a good strategy for eliminating the Mt bacteria. The aim of this study was to characterize four enzymes involved in Mt cell wall biosynthesis. In order to do that, they were produced recombinantly in E. coli and purified. Crystallization experiments were set up in order to produce diffracting crystals, with the aim of structure determination and drug design.

Mycobacterium tuberculosis

structure-based drug design

enzymes

cloning

expression

purification

crystallization

Ligand-associated conformational changes of a flexible enzyme captured by harnessing the power of allostery

Dean, Sondra Faye

01 December 2016

Flexible enzymes are notoriously a bane to structure-based drug design and discovery efforts. This is because no single structure can accurately capture the vast array of conformations that exist in solution and many are subject to ligand-associated structural changes that are difficult to predict. Glutamate racemase (GR) – an antibiotic drug discovery target involved in cell wall biosynthesis – is one such enzyme that has eluded basic structure-based drug design and discovery efforts due to these flexibility issues. In this study, our focus is on overcoming the impediment of unpredictable ligand-associated structural changes in GR drug discovery campaigns. The flexibility of the GR active site is such that it is capable of accommodating ligands with very different structures. Though these ligands may bind to the same pocket, they may associate with quite dissimilar conformations where some are more favorable for complexation than others. Knowledge of these changes is invaluable in guiding drug discovery efforts, indicating which compounds selectively associate with more favorable conformations and are therefore better suited for optimization and providing starting structures to guide structure-based drug design optimization efforts. In this study, we develop a mutant GR possessing a genetically encoded non-natural fluorescent amino acid in a region remote from the active site whose movement has been previously observed to correlate with active site changes. With this mutant GR, we observe a differential fluorescence pattern upon binding of two structurally distinct competitive inhibitors known to associate with unique GR conformations – one to a favorable conformation with a smaller, less solvated active site and the other to an unfavorable conformation with a larger, more solvated active site. A concomitant computational study ascribes the source of this differential fluorescence pattern to ligand-associated conformational changes resulting in changes to the local environment of the fluorescent residue. Therefore, this mutant permits the elucidation of valuable structural information with relative ease by simply monitoring the fluorescence pattern resulting from ligand binding, which indicates whether the ligand has bound to a favorable or unfavorable conformation and offers insight into the general structure of this conformation.

allostery

flexible enzymes

glutamate racemase

Pharmacy and Pharmaceutical Sciences

KINETIC AND MECHANISTIC CHARACTERIZATION OF HUMAN SULFOTRANSFERASES (SULT2B1b AND SULT1A1): DRUG TARGETS TO TREAT CANCERS

Yamasingha Pathiranage Kulathunga (16384296)

26 July 2023

<p>  </p> <p>Sulfonation is a widespread biological reaction catalyzed by a supergene family of enzymes called sulfotransferases (SULTs). SULTs utilize 3’-phosphoadenosine-5’-phospho-sulfate (PAPS) as the universal sulfonate donor to conjugate with a diverse range of endo- and xenobiotic substrates, including neurotransmitters, hormones, and drugs resulting in altering their biological activity. This reaction serves as a major detoxification pathway as conjugation with a sulfonate group renders substrates more hydrophilic and facilitates excretion. Therefore, this process is responsible for reducing the bioavailability of some drugs. In some cases, sulfo-conjugation causes the bio-activation of pro-mutagens and pro-carcinogens, leading to SULTs being risk factors in some cancers. Despite the biological relevance, understanding of this family of enzymes is still scarce. One SULT member that is the focus of the studies described herein is human sulfotransferase 2B1b (SULT2B1b), which had been identified as a potential drug target in prostate cancer. However, the inconsistency in reported kinetic data obtained using radiolabeled assays and the lack of robust assays have become significant limitations for SULT2B1b-targeted drug discovery studies. A label-free assay was developed to bridge this knowledge gap that directly quantifies SULT2B1b sulfonated products. This novel assay utilized high-throughput technology based on Desorption Electrospray Ionization Mass Spectrometry (DESI-MS). Results obtained from the DESI-MS-based assay were compared with those from a fluorometric, coupled-enzyme assay already developed in the Mesecar lab. Both methods provided consistent kinetic data for the reaction of SULT2B1b. Therefore, this novel assay is promising for the application of drug discovery efforts aiming at identifying SULT2B1b inhibitors. The other SULT member studied and described herein is human sulfotransferase 1A1 (SULT1A1), one of humans' most vital detoxifying and drug-metabolizing SULT isoforms that can also be a potential drug target in some cancers. The detailed kinetic mechanism of SULT1A1 was elucidated using steady-state kinetic, product inhibition, dead-end inhibition, and X-crystallographic studies. to gain insights into the role of this enzyme in detoxification, drug metabolism, and the development of inhibitors.</p>

Enzymes

Analytical spectrometry

enzyme kinetics experiment

structure-based drug design studies

Assay development studies

Structure-guided Synthesis and Evaluation of Non-nucleoside Reversible, Competitive Inhibitors of Human Ribonucleotide Reductase as Anti-proliferative Agents

Huff, Sarah

06 September 2017

No description available.

Organic Chemistry

MOLECULAR AND MACRO-MOLECULAR CYCLIZATION: STRUCTURE BASED DRUG DESIGN OPPORTUNITIES FOR TWO LYASE ENZYMES

Vijayaraghavan, Jagamya

05 June 2017

No description available.

Biochemistry

Discovery of novel small molecule enzyme inhibitors and receptor modulators through structure-based computational design

Mahasenan, Kiran V.

20 June 2012

No description available.

Pharmaceuticals

Pharmacy Sciences

structure-based drug design

computer-aided drug design

virtual screening

protein modeling

Design and synthesis of small molecule chemical probes for bromodomain-containing proteins

Hay, Duncan A.

January 2014

Bromodomains (BRDs) are protein modules which bind to acetylated lysines on histones and transcriptional regulating proteins. BRD-containing proteins are involved in a large variety of critical cellular processes and their misregulation, or mutation of the genes encoding for them, has been linked to pathogenesis in humans. The generation of chemical probes (potent, selective and cell permeable small molecules) in cellular experiments to investigate the biological role of the BRDs is thus desirable. A chemical probe for the CREB (cyclic-AMP response element binding protein) binding-protein (CBP) and E1A binding protein (p300) BRDs was developed, starting from a low molecular weight, weak and non-selective dimethylisoxazole benzimidazole compound. Parallel synthesis was used to optimise the initial hit into a weak, but selective CBP inhibitor. Further modification of the two N-1 and C-2 moieties of the benzimidazole scaffold, led to highly potent and selective CBP inhibitors. Structure-guided design was then applied to optimise the selectivity of the series for CBP over the first domain of bromodomain-containing protein 4 BRD4(1). A strategy to reduce the flexibility of the N-1 and C-2 ethylene linker groups through the incorporation of conformational constraints led to inhibitors with increased selectivity. The optimal compound was highly potent for the CBP and p300 BRDs (K_d 21 nM and 32 nM, respectively) and selective over BRD4(1) (40-fold and 27-fold, respectively). On-target cellular activity was observed in a fluorescence recovery after photobleaching (FRAP) assay (0.1 μM), a p53 reporter gene assay (IC₅₀ 1.5 μM) and a Förster resonance energy transfer (FRET) assay (5 μM). A weak indolizine bromodomain-containing protein 9 (BRD9) inhibitor was used as the starting point for the development of a BRD9/BRD7 chemical probe. Analogues were synthesised via [3+2] cycloadditions. An optimised compound was found to be highly potent (68 nM) and selective over BRD4(1) (34-fold). On-target cellular activity was observed in a FRAP assay (5 μM). Efforts were made to improve the cellular activity through the introduction of an ionisable centre to aid solubility. A selection of piperazine analogues were shown to be potent and selective, and these compounds warrant further investigation of their selectivity and cellular activity. Overall, the work has led to the first potent and selective inhibitors of the CBP/p300 and BRD9 BRDs. It also highlights the role of structural analysis in the development of inhibitors that modulate protein-protein interactions.

572

An effective layered workflow of virtual screening for identification of active ligands of challenging protein targets

Folly da Silva Constantino, Laura

01 August 2017

Docking is a computer simulation method used to predict the preferred orientation of two interacting chemical species that has been successfully applied to numerous macromolecules over the years. However, non-traditional targets have inherent difficulties associated with their screening. Large interfaces, lack of obvious binding sites, and transient pockets are some examples. Additionally, most natural ligands of challenging targets are inadequate models for identifying or designing new ligands. Therefore, it is not surprising that customary techniques of structure-based virtual screening are incompatible with these non-traditional targets. We hypothesized that an integrative virtual screening campaign comprised of docking followed by refinement of best receptor–ligand complexes would effectively identify small-molecule ligands of challenging receptors. We targeted the single-stranded DNA (ssDNA) binding groove of the human RAD52, and a cryptic allosteric pocket of the Helicobacter pylori Glutamate Racemase (GR). In this project, we first determined which docking method was more appropriate for each studied non-traditional target, and then examined how good our two-step docking workflow was in finding novel active ligand scaffolds. This research developed a powerful layered virtual screening workflow for the discovery of lead compounds against challenging protein targets. Furthermore, we successfully applied a statistical analysis method, which used receiver operating characteristic (ROC) curves, to validate the selected docking protocol that would be used in the screening campaigns. Using the validated workflow, we identified a natural compound that competes with ssDNA to bind to RAD52. The performed screening campaigns also provided new insights into the studied binding pockets, as well as structure-activity relationships (SAR) and binding determinants of the ligands. Our achievements reinforce the power of the ROC curve analysis approach in directing the search for the most appropriate docking protocol and helping to speed up drug discovery in pharmaceutical research.

allostery

docking

non-traditional targets

protein-nucleic acid interactions

ROC curves

Pharmacy and Pharmaceutical Sciences

Molecular characterization of insulin-regulated aminopeptidase (IRAP)

Ye, Siying

Unknown Date

Central infusion of the hexapeptide angiotensin IV (Ang IV) and its analogs have been demonstrated to markedly enhance memory retention and retrieval in rats using a range of learning and memory paradigms. This effect is mediated by the binding of the peptide to the specific binding site previously described as the AT4 receptor. The AT4 receptor has been isolated and identified as insulin-regulated aminopeptidase (IRAP), a type II transmembrane protein belonging to the M1 family of zinc-dependent aminopeptidases. Subsequently, AT4 receptor ligands, including Ang IV and its analogues and the unrelated peptide LVV-hemorphin-7, were demonstrated to be peptide inhibitors of IRAP. These findings suggest that AT4 ligands may exert their cognitive effects by inhibiting the catalytic activity of IRAP in the brain. Therefore, IRAP is an important target for the development of a new class of therapeutic agents for the treatment of memory loss. / To characterize IRAP at the molecular level and identify non-peptide inhibitors of IRAP for drug development, the aims of this study were to: 1) determine whether IRAP exists as a homodimer; 2) identify cysteine residue(s) involved in IRAP dimerization; 3) investigate the roles of the conserved residues of the HEXXH(X)18E Zn2+-binding motif and the GAMEN motif in substrate/inhibitor binding using site-directed mutagenesis; 4) use a molecular model of the catalytic domain of IRAP based on the crystal structure of a related M1 family metallopeptidase to: (i) identify key residues required for substrate/inhibitor binding; (ii) identify and characterize non-peptide IRAP inhibitors from a compound database by in silico virtual screening based on the homology model of IRAP. / Co-immunoprecipitation followed by Western blotting of IRAP under reducing and non-reducing conditions showed IRAP exists both as covalently- and non-covalently-bound homodimers. Serine scanning of cysteine residues potentially involved in forming inter-molecule disulfide-bonds was performed. Mutational analyses indicated that covalent homodimerization of IRAP is due to more than one cysteine residue. Limited trypsin digestion followed by co-immunoprecipitation suggests that non-covalent homodimerization of IRAP involves residues/regions within the last 130 amino acids of the protein. / The catalytic site of IRAP contains two consensus motifs, the H464EXXH468(X)18E487 Zn2+-binding motif and the G428AMEN432 motif. The role of conserved residues with these motifs was investigated using site-directed mutagenesis and pharmacological analyses. The conserved His and Glu residues of the Zn2+-binding motif were shown to be essential for IRAP catalytic activity. This was also observed for the Met and Glu residues of the GAMEN motif, while Asn mutant retained some catalytic activity. Residues important for substrate or inhibitor binding were identified as Gly, Ala and Asn. / A molecular model of the catalytic domain of IRAP based on the crystal structure of a homologous M1 metallopeptidase, leukotriene A4 hydrolase (LTA4H) was used to compare the catalytic sites of IRAP and LTA4H, and identified two amino acids at the putative substrate-binding pocket: Ala427 and Leu483 in IRAP, and the corresponding residues Tyr267 and Phe314 in LTA4H. A mutational analysis involving substitution of Ala427 and Leu483 with the corresponding residues revealed Ala427 and Leu483 characterize the enzyme S1 subsite, influencing the affinity and placement of substrates and peptide inhibitors in the catalytic site. / The molecular model of IRAP was also used for virtual screening of compound databases to identify novel non-peptide inhibitors. After two rounds of in silico screening, a family of compounds was identified and shown to be specific and competitive inhibitors of IRAP. Preliminary results suggest that one of these inhibitors, referred to as HFI 142, may possess memory-enhancing properties. The identification of non-peptide IRAP inhibitors will assist in pharmacological studies aimed at understanding the molecular mechanisms of IRAP aminopeptidase activity and physiological role of IRAP. In addition, the new inhibitors have the potential to form the basis for the development of a novel class of drugs useful for treating memory disorders.