Characterizing Microglial Response to Amyloid: From New Tools to New Molecules

Priya Prakash (10725291)

29 April 2021

<p>Microglia are a population of specialized, tissue-resident immune cells that make up around 10% of total cells in our brain. They actively prune neuronal synapses, engulf cellular debris, and misfolded protein aggregates such as the Alzheimer’s Disease (AD)-associated amyloid-beta (Aβ) by the process of phagocytosis. During AD, microglia are unable to phagocytose Aβ, perhaps due to the several disease-associated changes affecting their normal function. Functional molecules such as lipids and metabolites also influence microglial behavior but have primarily remained uncharacterized to date. The overarching question of this work is, <i>How do microglia become dysfunctional in chronic inflammation</i>? To this end, we developed new chemical tools to better understand and investigate the microglial response to Aβ <i>in vitro</i> and <i>in vivo</i>. Specifically, we introduce three new tools. (1) Recombinant human Aβ was developed via a rapid, refined, and robust method for expressing, purifying, and characterizing the protein. (2) A pH-sensitive fluorophore conjugate of Aβ (called Aβ^pH) was developed to identify and separate Aβ-specific phagocytic and non-phagocytic glial cells <i>ex vivo</i> and <i>in vivo</i>. (3) New lysosomal, mitochondrial, and nuclei-targeting pH-activable fluorescent probes (called LysoShine, MitoShine, and NucShine, respectively) to visualize subcellular organelles in live microglia. Next, we asked, <i>What changes occur to the global lipid and metabolite profiles of microglia in the presence of Aβ in vitro and in vivo</i>? We screened 1500 lipids comprising 10 lipid classes and 700 metabolites in microglia exposed to Aβ. We found significant changes in specific lipid classes with acute and prolonged Aβ exposure. We also identified a lipid-related protein that was differentially regulated due to Aβ <i>in vivo</i>. This new lipid reprogramming mechanism “turned on” in the presence of cellular stress was also present in microglia in the brains of the 5xFAD mouse model, suggesting a generic response to inflammation and toxicity. It is well known that activated microglia induce reactive astrocytes during inflammation. Therefore, we asked, <i>What changes in proteins, lipids, and metabolites occur in astrocytes due to their reactive state? </i>We provide a comprehensive characterization of reactive astrocytes comprising 3660 proteins, 1500 lipids, and 700 metabolites. These microglia and astrocytes datasets will be available to the scientific community as a web application. We propose a final model wherein the molecules secreted by reactive astrocytes may also induce lipid-related changes to the microglial cell state in inflammation. In conclusion, this thesis highlights chemical neuroimmunology as the new frontier of neuroscience propelled by the development of new chemical tools and techniques to characterize glial cell states and function in neurodegeneration.</p>

Cell Biology

Neuroscience

Medical Biochemistry: Lipids

Cellular Immunology

Analytical Biochemistry

Cell Neurochemistry

Immunological and Bioassay Methods

Biologically Active Molecules

Microglia

Alzheimer's disease

Lipidomics

Proteomics

Metabolomics

Phagocytosis

Amyloid Beta

Astrocytes

Reactive Astrocytes

Chemical Tools

Chemical Biology

Neuroinflammation

Neurodegeneration

Glia

Neuroscience

Neuroimmunology

ACCELERATING DRUG DISCOVERY AND DEVELOPMENT USING ARTIFICIAL INTELLIGENCE AND PHYSICAL MODELS

Godakande Kankanamge P Wijewardhane (15350731)

25 April 2023

<p>Drug discovery and development has experienced a tremendous growth in the recent</p> <p>years, and methods to accelerate the process are necessary as the demand for effective drugs</p> <p>to treat a wide range of diseases continue to increase. Nevertheless, the majority of conventional</p> <p>techniques are labor-intensive or have relatively low yields. As a result, academia</p> <p>and the pharmaceutical industry are continuously seeking for rapid and efficient methods to</p> <p>accelerate the drug discovery pipeline. Therefore, in order to expedite the drug discovery</p> <p>process, recent developments in physical and artificial intelligence models have been utilized</p> <p>extensively. However, the overarching problem is how to use these cutting-edge advancements</p> <p>in artificial intelligence to enhance drug discovery? Therefore, this dissertation work</p> <p>focused on developing and applying artificial intelligence and physical models to accelerate</p> <p>the drug discovery pipeline at different stages. As the first study reported in the dissertation,</p> <p>the potential to apply graph neural network-based machine learning architectures</p> <p>with the assistance of molecular modeling features to identify plausible drug leads out of</p> <p>structurally similar chemical databases is assessed. Then, the capability of applying molecular</p> <p>modeling methods including molecular docking and molecular dynamics simulations to</p> <p>identify prospective targets and biological pathways for small molecular drugs is discussed</p> <p>and evaluated in the following chapter. Further, the capability of applying state-of-the-art</p> <p>deep learning architectures such as multi-layer perceptron and recurrent neural networks</p> <p>to optimize the formulation development stage has been assessed. Moreover, this dissertation</p> <p>has contributed to assist functionality identification of unknown compounds using</p> <p>simple machine learning based computational frameworks. The developed omics data analysis</p> <p>pipeline is then discussed in order to comprehend the effects of a particular treatment</p> <p>on the proteome and lipidome levels of cells. In conclusion, the potential for developing and</p> <p>utilizing various artificial intelligence-based approaches to accelerate the drug discovery and</p> <p>development process is explored in this research. Thus, these collaborative studies intend</p> <p>to contribute to ongoing acceleration efforts and advancements in the drug discovery and</p> <p>development field.</p>

Biologically active molecules

Biomolecular modelling and design

Molecular medicine

Computational chemistry

Deep learning

Artificial intelligence models

machine learning

deep learning

Drug Discovery Development

Computational chemistry research

DEVELOPMENT OF TOOLS TO UNDERSTAND THE ROLE OF THE PBAF CHROMATIN REMODELER IN PROSTATE CANCER

Sandra Carolina Ordonez Rubiano (18115162)

06 March 2024

<p dir="ltr">The BRG1/BRM-associated factor (BAF) complexes, also called SWI/SNF, are multi-subunit chromatin remodelers that regulate chromatin compaction in an ATP-dependent manner. In the past decade, BAF complexes have been under the spotlight in cancer research, especially after proteomic analyses revealed the genes encoding the subunits are amongst the most frequently mutated genes in cancer. The present dissertation focuses on prostate cancer (PCa), a disease in which the role of the BAF subunits is increasingly being explored but is yet to be defined as a potential therapeutic target. According to the GLOBOCAN report, PCa is the second most frequent cancer in males worldwide. Since most of the variants of PCa rely on the androgen receptor (AR) axis, surgical or chemical castration and androgen deprivation therapy (ADT) are the main treatment strategies for PCa patients. Even though these therapeutic approaches prolong survival, reduce tumor burden, and relieve symptoms, PCa patients eventually relapse and develop castration resistant PCa (CRPC). At present, the mechanisms underlying ADT resistance are not fully understood, current efforts focus on finding new targets for PCa treatment.</p><p dir="ltr">In the projects included in this dissertation we explored the function of the PBAF complex, a BAF subtype, in a variety of models of PCa and its potential as a therapeutic target by inhibiting or depleting its different subunits. To do so we (i) developed the first inhibitors for BRD7 (a subunit unique to PBAF) and (ii) established cell-based assays in multiple PCa cell lines to study BRD7 and other PBAF unique subunits.</p><p dir="ltr">Bromodomain-containing proteins are readers of acetylated lysine and play important roles in cancer. Bromodomain-containing protein 7 (BRD7) has been implicated in multiple malignancies; however, there are no selective chemical probes to study its function in disease. Using crystal structures of BRD7 and BRD9 bromodomains (BDs) bound to BRD9-selective ligands, we identified a binding pocket exclusive to BRD7. We synthesized a series of ligands designed to occupy this binding region and identified two inhibitors with increased selectivity towards BRD7, 1-78 and 2-77, which bind with submicromolar affinity to the BRD7 BD. Our binding mode analyses indicate that these ligands occupy a uniquely accessible binding cleft in BRD7 and maintain key interactions with the asparagine and tyrosine residues critical for acetylated lysine binding. Finally, we validated the utility and selectivity of the compounds in cell-based models of prostate cancer.</p><p dir="ltr">There are three BAF complexes that have been biochemically characterized up to date: canonical BAF (cBAF), polybromo-associated BAF (PBAF) and GLTSCR1/like-containing BAF (GBAF or ncBAF). All BAF complexes are characterized by containing an ATPase and accessory subunits that may be shared between them or unique to each subtype. PBAF, the BAF subtype of interest of this dissertation, contains four unique subunits: BRD7, PBRM1, ARID2 and BAF45A. We showed that knocking down BRD7 and ARID2 leads to reduction of cell viability in PCa cells with ligand-dependent and independent AR signaling, while knocking down PBRM1 leads to reduction in viability of cells with only ligand-dependent AR signaling. We also performed a chromatin immunoprecipitation assay with BAF45A and observed that it does not colocalize with AR binding sites, indicating that the mechanism by which PBAF regulates AR signaling is indirect. This observation was further supported by the fact that knocking down BRD7 prevents expression of genes related to adaptive processes, but not AR target genes, in response to androgen treatment. Further mechanistic studies will aid in understanding the function of PBAF in PCa. However, overall, our results indicate that PBAF is a promising therapeutic target in PCa models expressing AR, including CRPC systems.</p>

Genomics

Biologically active molecules

Biomolecular modelling and design

Organic chemical synthesis

Prostate cancer

Epigenetics

BRD7

SWI/SNF-complex

Small molecule inhibitors

DISTINCT ROLES OF THE aD HELIX IN aCAMKII ACTIVATION CHARACTERIZED USING A DE NOVO MUTATION FROM CHILDREN WITH LEARNING DISABILITIES

Walter Saide (16650807)

07 August 2023

<p>This dissertation describes the effects of a <i>de novo</i> mutation of CaMKII found in children with learning disabilities and describes its effect on catalytic activity. We develop a malachite green assay for the measurement of CaMKII activation and use it for high-throughput chemical screening to identify CaMKII inhibitors and enhancers. We also propose a new mechanism of regulation of CaMKII activity by ADP.</p><p><br></p>

Cell neurochemistry

Enzymes

Basic pharmacology

Biologically active molecules

Biomolecular modelling and design

Proteins and peptides

Catalysis and mechanisms of reactions

Reaction kinetics and dynamics

CaMKII α

learning and memory impairment

calmodulin

calcium signaling

kinase activity

medicinal chemistry

molecular pharmacology

enzyme kinetics

western blotting

biochemistry

molecular modeling

high throughput chemical screening

assay development

protein structure

enzyme coupled assays

malachite green assay

cellular biology

fluorescence microscopy

hplc

lc-ms/ms

autophosphorylation

ATP:ADP ratios