Browsing by Author "Richardson, Timothy I."
Now showing 1 - 10 of 13
Results Per Page
Sort Options
Item A guide to selecting high-performing antibodies for PLC-gamma-2 for use in Western Blot, immunoprecipitation and immunofluorescence(Taylor & Francis, 2024-01-18) Ruíz Moleón, Vera; Fotouhi, Maryam; Alende, Charles; Ayoubi, Riham; Bedford, Logan M.; Southern, Kathleen; Richardson, Timothy I.; Laflamme, Carl; NeuroSGC/YCharOS/EDDU collaborative group; ABIF consortium; Pharmacology and Toxicology, School of MedicinePhosphatidylinositol-specific phospholipase C gamma 2 (PLC-gamma-2) is an enzyme that regulates the function of immune cells. PLC-gamma-2 has been implicated in neurodegenerative and autoimmune disorders, yet investigation of this protein has been limited by a lack of independently characterized antibodies. Here we have characterized eleven PLC-gamma-2 commercial antibodies for use in Western Blot, immunoprecipitation, and immunofluorescence using a standardized experimental protocol based on comparing read-outs in knockout cell lines and isogenic parental controls. These studies are part of a larger, collaborative initiative seeking to address antibody reproducibility issues by characterizing commercially available antibodies for human proteins and publishing the results openly as a resource for the scientific community. While use of antibodies and protocols vary between laboratories, we encourage readers to use this report as a guide to select the most appropriate antibodies for their specific needs.Item AD Informer Set: Chemical tools to facilitate Alzheimer's disease drug discovery(Wiley, 2022-04-20) Potjewyd, Frances M.; Annor-Gyamfi, Joel K.; Aubé, Jeffrey; Chu, Shaoyou; Conlon, Ivie L.; Frankowski, Kevin J.; Guduru, Shiva K.R.; Hardy, Brian P.; Hopkins, Megan D.; Kinoshita, Chizuru; Kireev, Dmitri B.; Mason, Emily R.; Moerk, Charles T.; Nwogbo, Felix; Pearce, Kenneth H.; Richardson, Timothy I.; Rogers, David A.; Soni, Disha M.; Stashko, Michael; Wang, Xiaodong; Wells, Carrow; Willson, Timothy M.; Frye, Stephen V.; Young, Jessica E.; Axtman, Alison D.; Medicine, School of MedicineIntroduction: The portfolio of novel targets to treat Alzheimer's disease (AD) has been enriched by the Accelerating Medicines Partnership Program for Alzheimer's Disease (AMP AD) program. Methods: Publicly available resources, such as literature and databases, enabled a data-driven effort to identify existing small molecule modulators for many protein products expressed by the genes nominated by AMP AD and suitable positive control compounds to be included in the set. Compounds contained within the set were manually selected and annotated with associated published, predicted, and/or experimental data. Results: We built an annotated set of 171 small molecule modulators targeting 98 unique proteins that have been nominated by AMP AD consortium members as novel targets for the treatment of AD. The majority of compounds included in the set are inhibitors. These small molecules vary in their quality and should be considered chemical tools that can be used in efforts to validate therapeutic hypotheses, but which will require further optimization. A physical copy of the AD Informer Set can be requested on the Target Enablement to Accelerate Therapy Development for Alzheimer's Disease (TREAT-AD) website. Discussion: Small molecules that enable target validation are important tools for the translation of novel hypotheses into viable therapeutic strategies for AD.Item Develop the Disease Specific Bioinformatics Platforms with Integrated Bioinformatics Data(2022-11) Liu, Jiannan; Yan, Jingwen; Zhang, Jie; Huang, Kun; Zhang, Chi; Richardson, Timothy I.; Wu, HuanmeiWith the advance of multiple types of omics technology and corresponding analytical methods, various type of bioinformatic data have become available. Mining and integrating these data for analysis will provide valuable insights for disease mechanism investigation, drug target identification and new drug development. However, most of the omics data are large size, heterogeneous, and complex, it is challenging for biomedical researchers to mine the data for relevant evidence, especially for those with limited computational skills. In this thesis, I aimed to develop disease specific platforms integrated with multimodal bioinformatic data types to provide researchers with strong bioinformatics support. To achieve this goal, I explored advanced transcriptomic data analytical methods and proposed a novel biomarker for the prediction of overall survival of colon cancer patients, then prototyped a user-friendly patient oriented clinical decision support system to provide accurate and intuitive colorectal cancer risk factor assessment. With the experience of the transcriptomic data analytical methods and the web-based application development, I further designed and implemented Cancer Gene and Pathway Explorer which is an integrative bioinformatics webserver that can be used for cancer publication trends investigation, gene set enrichment analysis with integrated data, and optimal cancer cell line identification. Based on the framework of CGPE, I developed another bioinformatics platform focusing on Alzheimer’s disease, called Alzheimer’s Disease Explorer, which is a first-of-its-kind bioinformatics server, providing rich bioinformatic support from literature, omics and chemical data to facilitate researchers in ND drug development field. By accomplishing a series of work in my thesis, I have shown that integrated disease specific bioinformatics platforms can provide great value to the research community by allowing 1.) fast and accurate investigation of currently available literature, 2.) quick hypothesis generation and validation using transcriptomic datasets, 3.) multi-dimension drug target evaluation and 4) fast querying of published bioinformatics outcomes.Item Exploring Class‐II PI3K Inhibition for the treatment of Alzheimer’s Disease: Virtual Screening for PI3KC2A Inhibitors(Wiley, 2025-01-09) Jadala, Chetna; Robo, Michael T.; Richardson, Timothy I.; Pharmacology and Toxicology, School of MedicineBackground: Focusing on novel AD treatments, the TREAT‐AD centers offer an array of free research tools, shared via the AD Knowledge Portal in a Target Enablement Package (TEP). This abstract showcases the research conducted by the IUSM‐Purdue TREAT‐AD Center, specifically focusing on Targeting class‐II PI3K’s as a potential breakthrough in AD therapy. Endocytosis within the brain encompasses diverse pathways for internalizing extracellular cargoes and receptors into cells. The prominent routes include clathrin‐mediated endocytosis and phagocytosis. Endocytosis plays a crucial role in processing amyloid precursor protein (APP) leading to abnormal production of Aβ peptides. Recycling endosomes are vital for delivering and eventually releasing Aβ into the brain. Recent research emphasizes the pivotal role of PI3K‐C2α, a class II PI3K member, in regulated endocytosis through its clathrin‐binding domain. Its localization spans clathrin‐coated pits, endocytic vesicles, early endosomes, and the trans‐Golgi network, generating phosphatidylinositol 3‐phosphate (PtdIns(3)P) and/or phosphatidylinositol 3,4‐bisphosphates (PtdIns(3,4)P2) in vivo. Targeting clathrin‐mediated endocytosis by inhibiting PI3K‐C2α, a key regulator in clathrin coated vesicle formation, could be a potential therapeutic strategy against Alzheimer’s disease. Method: We conducted extensive virtual screenings of vast compound libraries to determine potent small molecules inhibiting PI3K‐C2α. Employing shape‐based screening, and clustering techniques, we identified leading compounds for subsequent in vitro kinase assays. Compounds exhibiting nanomolar activity were selected for further investigation. Leveraging these findings, we conducted Structure‐Activity Relationship (SAR) studies, optimizing analogs to enhance binding affinity and cellular pharmacology. Result: We have identified novel PI3K‐C2α inhibitors and are in the initial stages of optimization. These compounds exhibit promising target engagement, pending further assessment for biochemical activity and cellular pharmacology. In silico assessments suggest their structures are ideal for CNS drug discovery plans. Conclusion: Inhibiting PI3K‐C2α stands as a promising therapeutic approach for Alzheimer’s disease. We've discovered unique molecular structures that inhibit the enzyme. Our findings suggest potential probe molecules for validating the target and developing lead compounds for clinical investigations.Item Generation and validation of anti‐TREM2 agonistic antibodies to enable the advancement of drug targets in the TREM2/DAP12 signaling pathway for the treatment of Alzheimer Disease(Wiley, 2025-01-09) Moussaif, Mustapha; Javens-Wolfe, June; Palkowitz, Alan D.; Richardson, Timothy I.; Pharmacology and Toxicology, School of MedicineBackground: TREM2 signaling has been implicated in Alzheimer’s Disease (AD). TREM2 regulates microglial states and functions such as phagocytosis. The most prominent TREM signaling adapter is DAP12, encoded by TYROBP. Understanding functional changes of this complex, and downstream effectors such as SHIP1, PLCG2 and the Scr family kinases Lyn and Hck, is required to evaluate a broad range of therapeutic hypotheses and drug targets for prioritization and enablement. The lack of available, well validated, and openly distributed experimental tools can limit early drug discovery efforts. Therefore, the IUSM Purdue TREAT‐AD Center has generated and validated TREM2 activating antibodies to enable the advancement of drug targets in the TREM2/DAP12 signaling pathway. Method: To establish and validate anti‐TREM2 agonist antibodies, heavy and light chain variable sequences were identified from multiple publications including patent applications. Antibodies were formatted as either human IgG1, Fc null mutant IgG1 or antibody transport vehicle (ATV) Fc null mutant IgG1. They were expressed in mammalian ExpiCHO cells and tested ex vivo for agonism based on their ability to activate AKT and Syk phosphorylation in THP1 cells and TREM2/DAP12 overexpressing cells respectively. The strongest agonistic candidate was scaled, purified, and further characterized biophysically and functionally. Result: Several agonistic antibodies were identified. AL2p31 antibody showed binding specificity to human versus murine TREM2. Biophysical characterization using biolayer interferometry showed that binding kinetic parameters (KD, Kon, and Koff) were not significantly affected in LALAPG null mutant Fc background. AL2p31 specifically induced Syk phosphorylation in comparison to an isotype control. Analysis of antibodies formatted as bispecific IgG1 targeting both TREM2 and the human transferrin receptor (hTfR), confirmed that RS9‐F6 can bind both human and murine TREM2 and revealed the ATV 35‐21‐16 variant sequence as a binder for the hTfR. Conclusion: The mission of the IUSM Purdue TREAT‐AD Center is to enable and advance the next generation of drug targets for the treatment of AD. The validation of anti‐TREM2 agonistic antibodies as research tools will enable comprehensive studies of the TREM2/DAP12 signaling and potential drug targets within the pathway including SHIP1, PLCG2 and the Scr family kinase Lyn and Hck.Item Identification of Chemical Tool Compounds to Investigate the Role of Lyn Kinase in TREM2‐Mediated Microglia Activation and Phagocytosis(Wiley, 2025-01-09) Weerawarna, Pathum M.; Robo, Michael T.; Chu, Shaoyou; Mason, Emily R.; Davis, Chris; Angus, Steven P.; Richardson, Timothy I.; Medicine, School of MedicineBackground: Lyn kinase, a member of the Src family of tyrosine kinases, predominantly phosphorylates ITIM and ITAM motifs linked to immune receptors and adaptor proteins, and is emerging as a target for Alzheimer’s disease (AD). The role of Lyn in TREM2‐mediated microglial activation and phagocytosis, a critical pathway for clearing Aβ plaques, remains unclear and potent, selective, and brain penetrant Lyn inhibitors are unavailable. In this study, we report the characterization of Lyn kinase inhibitors from the literature as well as the establishment of an advanced virtual screening platform at the IUSM‐Purdue‐TREAT‐AD center to identify new type II Lyn inhibitors suitable as molecular probes. Method: We first performed a thorough literature survey and found 14 reported Lyn kinase inhibitors. We then validated their Lyn inhibitor activities and Lyn selectivities using the HotSpot kinase assay. We tested these compounds for microglia activation in a high‐content imaging assay using HMC3 (human) and BV2 (mouse) microglia‐like cell lines. We also performed kinome profiling in these cells to evaluate cellular target engagement and selectivity. Finally, we screened a million‐compounds using a computational pipeline that combined molecular docking, shape‐based screening, and MD simulations to identify novel and potent type II Lyn kinase inhibitors. Result: Our findings revealed that Type I inhibitors, particularly Saracatinib and Bosutinib, potently inhibit Lyn within the picomolar (pM) range. On the other hand, Type II inhibitors, such as Masitinib and Imatinib, displayed pronounced >20‐fold selectivity for Lyn over Hck with low nM Lyn inhibitor activities. Saracatinib and Bosutinib significantly induced phagocytosis in HMC3 cells, whereas Type II inhibitors demonstrated moderate activity in both HMC3 and BV2 cells. Our virtual screening platform identified a new type II Lyn inhibitor with picomolar activity and good Lyn/Hck selectivity. Conclusion: We have successfully evaluated previously reported inhibitors and introduced a novel type II Lyn kinase inhibitor with picomolar (pM) activities suitable for use as chemical probes to investigate the role of Lyn in TREM2‐mediated microglial activation.Item Identification of PLCG2 activators for the treatment of Alzheimer’s disease(Wiley, 2025-01-09) Clayton, Brent; Massey, Steven M.; Beck, Daniel E.; Putt, Karson S.; Utsuki, Tada; Visvanathan, Ramya; Mesecar, Andrew D.; Lendy, Emma K.; Kaiser, Bridget L.; Chu, Shaoyou; Mason, Emily R.; Lamb, Bruce T.; Palkowitz, Alan D.; Richardson, Timothy I.; Pharmacology and Toxicology, School of MedicineBackground: The goal of the TREAT‐AD Center is to enable drug discovery by developing assays and providing tool compounds for novel and emerging targets. The role of microglia in neuroinflammation has been implicated in the pathogenesis of Alzheimer’s disease (AD). Genome‐wide association studies, whole genome sequencing, and gene‐expression network analyses comparing normal to AD brain have identified risk and protective variants in genes essential to microglial function. among them. The P522R variant of phospholipase C gamma2 (PLCγ2) is associated with reduced risk for AD and has been characterized as a functional hypermorph. Carriers of P522R with mild cognitive impairment exhibited a slower cognitive decline rate. Conversely the M28L variant increases risk. Therefore, activation of the protein PLCγ2 with small molecules has been proposed as a therapeutic strategy to reduce the rate of disease progression and cognitive decline in AD patients. Method: We performed a high‐throughput screen using affinity selection mass spectrometry (ASMS) to identify novel small molecules that bind to the full‐length protein PLCγ2. A Cellular Thermal Shift Assay (CETSA) was developed to confirm target engagement in cells. A liposomal‐based, fluorogenic reporter biochemical assay was implemented to evaluate activity of the enzyme. A high‐content imaging assay measuring phagocytosis, cell number, and nuclear intensity was carried out using the BV2 and HMC3 cell lines to characterize cellular pharmacology and cytotoxicity. Structure activity relationship (SAR) studies were performed to synthesize analogs and optimize for binding and cellular pharmacology. Optimized compounds have been studied in vivo to assess pharmacokinetic properties and drug likeness. Result: Novel PLCγ2 activators have been discovered and preliminary optimization has been completed. These compounds have shown positive results for target engagement, biochemical activity, and cellular pharmacology. In silico predictions indicated the molecule structures are suitable CNS drug discovery program starting points. Conclusion: Activation of PLCγ2 is a novel therapeutic strategy for treatment of AD. We identified structurally distinct molecular scaffolds capable of enzyme activation and cellular activity. Recommendations for use of probe molecules in target validation studies and the development of lead‐like molecules for clinical studies will be made.Item Inhibition of Lyn kinase: A novel approach to treatment of Alzheimer’s disease(Wiley, 2025-01-09) Benitah, Avi L.; Richardson, Timothy I.; Weerawarna, Pathum M.; Robo, Michael T.; Mason, Emily R.; Pharmacology and Toxicology, School of MedicineBackground: The TREAT‐AD centers aim to improve Alzheimer’s Disease (AD) research by offering free, high‐quality tools and technologies. Lyn is a tyrosine kinase that belongs to the Src family kinases. The expression of Lyn and its activity have been implicated in AD. This class of proteins is involved in TREM2 mediated microglial activation and phagocytosis, a process which is beneficial for clearing neurotoxins such as Aβ oligomers in the brain. Lyn inhibition may activate microglia. Given the relationship between accumulation of Aβ and its exacerbation of neurodegenerative diseases such as AD, selective inhibition of Lyn has been proposed as a novel therapeutic approach to treating early‐onset AD. However, potent, selective, and brain penetrant Lyn inhibitors are unavailable to test this hypothesis. Method: We screened a variety of known kinase inhibitors to determine their activity towards inhibition of Lyn using the biochemical HotSpot kinase assay. With this data in hand, we identified imatinib as a starting point for the design of novel Lyn inhibitors. Structure‐based design and computational docking models were used to propose more active and selective Lyn inhibitors, which were synthesized. The activities were determined, and multiple parameter optimization (MPO) informed iterative Structure Activity Relationship (SAR) studies. The best compounds were evaluated in assays of microglia activation, and their drug metabolism and pharmacokinetic (DMPK) properties were determined. Result: A series of novel type II inhibitors are now available for testing. The results demonstrate a unique tail group provides the novel scaffold with potent activity and selectivity towards inhibition of Lyn, exceeding that of imatinib. Conclusion: Computational models, SAR, and MPO provided potent and selective Lyn inhibitors with good DMPK properties. Further studies are under way to determine the impact of these compounds on TREM2 mediated activation of microglia both in vitro and in vivo.Item IUSM‐Purdue TREAT‐AD Center Capabilities and Strategy to Enable and Advance Novel Therapeutic Targets for the Treatment of Alzheimer’s Disease(Wiley, 2025-01-09) Mowery, Stephanie A.; Huang, Kun; Mesecar, Andrew D.; Dage, Jeffrey L.; Clayton, Brent; Lamb, Bruce T.; Palkowitz, Alan D.; Richardson, Timothy I.; Neurology, School of MedicineBackground: The TaRget Enablement to Accelerate Therapy Development of Alzheimer’s Disease (TREAT‐AD) Centers are dedicated to identifying and validating targets from the NIH Accelerating Medicines Partnership for Alzheimer’s Disease (AMP‐AD). The centers develop Target Enabling Packages (TEPs) to explore new therapeutic target hypotheses, moving beyond the traditional focus on amyloid or tau pathologies. In accordance with open science principles, data, methods, and tools are freely shared with the research community via an open‐access platform, the AD Knowledge Portal. The Indiana University School of Medicine and Purdue University TREAT‐AD (IUSM Purdue TREAT‐AD) Center comprises four technical cores: Bioinformatics and Computational Biology (BCB), Structural Biology and Biophysics Core (SBB), Assay Development and High Throughput Screening (ADHTS), and Medicinal Chemistry and Chemical Biology (MCCB). These cores collaborate to develop research tools that are used to validate biological targets and assess their druggability with an initial focus on understanding the role of neuroinflammation in AD. Method: The BCB Core supports target selection and validation with data and analysis. The SBB Core provides proteins for assay development, biophysical assays, and structural studies to aid in mode of action and Structure Activity Relationship (SAR) studies. The ADHTS Core develops in vitro and in vivo assays for SAR studies and translational PD biomarker strategies to assist in determining early phase clinical dosing regimens. The MCCB Core selects therapeutic modalities (small molecules, antibodies, siRNA) and discovers pharmacological tools, employing strategies for SAR studies to balance pharmacological and drug‐like properties. Result: Target Enabling Packages (TEPs) are now available via the AD Knowledge Portal for microglia targets that were prioritized for early drug discovery studies. TEPs include bioinformatics analysis, biological reagents and protocols, protein production methods, and recommended chemical probes with detailed information (Figure 1). Novel small molecule hits and leads were identified for SHIP1, PLCG2, SHP1 and LYN/HCK. Conclusion: A pipeline of prioritized microglia targets were selected and enabled for early drug discovery. The IUSM Purdue TREAT‐AD Center is now working with AMP‐AD researchers to explore biological hypothesis in addition to the role of neuroinflammation in AD.Item Optimization of SHIP1 Inhibitors for the treatment of Alzheimer’s disease(Wiley, 2025-01-09) Jesudason, Cynthia D.; Lin, Peter Bor-Chian; Soni, Disha; Perkins, Bridget M.; Lee-Gosselin, Audrey; Ingraham, Cynthia M.; Hamilton, Will; Mason, Emily R.; El Jordi, Omar; Souza, Sarah; Jacobson, Marlene; Di Salvo, Jerry; Clayton, Brent; Chu, Shaoyou; Dage, Jeffrey L.; Oblak, Adrian L.; Richardson, Timothy I.; Neurology, School of MedicineBackground: SHIP1 is a phosphatidyl inositol phosphatase encoded by INPP5D, which has been identified as a risk gene for Alzheimer’s disease (AD). SHIP1 is expressed in microglia, the resident macrophage in brain. It is a complex, multidomain protein that acts as a negative regulator downstream from TREM2. SHIP1 possesses a phosphatase (Ptase) domain flanked by a pleckstrin‐homology (PH) domain that binds phosphatidylinositol (3,4,5)‐trisphosphate[PI(3,4,5)P3] and a C2 domain that binds phosphatidylinositol (3,4)‐bisphosphate [PI(3,4)P2]. The Ptase domain converts PI(3,4,5)P3 to PI(3,4)P2. SHIP1 also has an SH2 domain that binds to ITIMs and ITAMs where it competes with kinases. Inhibiting SHIP1 is hypothesized to have potential therapeutic benefits, as it may improve TREM2‐mediated microglial responses to neurotoxins and promote an overall neuroprotective microglial phenotype to maintain a more resilient brain and slow the rate of cognitive decline in AD patients. Method: The IUSM Purdue TREAT‐AD Center recently evaluated SHIP1 inhibitors and proposed 3‐((2,4‐Dichlorobenzyl)oxy)‐5‐(1‐(piperidin‐4‐yl)‐1H‐pyrazol‐4‐yl)pyridine for target validation studies. Structurally related analogs were synthesized and tested for SHIP1 enzyme inhibition, AKT signaling, and microglia activation in a high‐content imaging assay using HMC3 and BV2 microglia‐like cell lines. Primary microglia were treated with an optimized SHIP1 inhibitor, and subsequent changes in fibril Aβ uptake and cell viability were assessed. The NanoString nCounter Neuroinflammation assay was used to measure transcriptomic profiles. For comparison primary microglial derived from both wild‐type and Inpp5d‐haploinsufficient mice were assessed. Result: Novel SHIP1 inhibitors have been discovered and preliminary Structure Activity Relationship (SAR) studies have been completed. These compounds have shown positive results for biochemical activity, target engagement and cellular pharmacology. Both Inpp5d deficiency and pharmacological inhibition increase amyloid uptake and cell viability in primary microglia. Elevated ERK and AKT phosphorylation, after amyloid exposure, were decreased by Inpp5d deficiency. Functional pathways associated with phagocytosis, apoptosis, cytokine production, and complement system activity were altered. Conclusion: These data demonstrate that SHIP1 inhibition promotes amyloid uptake through the complement system. SHIP1 inhibition also enhances cell survival and homeostasis in primary microglia. Further studies of SHIP1 inhibition and INPP5D knockdown in animal models may provide a potential therapeutic strategy for Alzheimer’s disease.