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A multi-disciplinary Institute within the University of Oxford which focuses upon translational activities to catalyse the discovery of new medicines.
Single-cell transcriptomics defines an improved, validated monoculture protocol for differentiation of human iPSC to microglia.
There is increasing genetic evidence for the role of microglia in neurodegenerative diseases, including Alzheimer's, Parkinson's, and motor neuron disease. Therefore, there is a need to generate authentic in vitro models to study human microglial physiology. Various methods have been developed using human induced Pluripotent Stem Cells (iPSC) to generate microglia, however, systematic approaches to identify which media components are actually essential for functional microglia are mostly lacking. Here, we systematically assess medium components, coatings, and growth factors required for iPSC differentiation to microglia. Using single-cell RNA sequencing, qPCR, and functional assays, with validation across two labs, we have identified several medium components from previous protocols that are redundant and do not contribute to microglial identity. We provide an optimised, defined medium which produces both transcriptionally and functionally relevant microglia for modelling microglial physiology in neuroinflammation and for drug discovery.
Variation on a theme: mapping microglial heterogeneity.
Young et al. examine the complexity of primary human microglia, and identify previously unknown cell states. Using expression quantitative trait locus (eQTL) mapping techniques, they identify 129 genes whose expression in microglia is linked to disease, and show that induced pluripotent stem cell (iPSC) models can be used for functional validation of common genetic mutations in microglia-associated diseases.
A High-Throughput Drug Repurposing Strategy to Treat TBX2 and/or TBX3 Dependent Cancers.
BACKGROUND: The highly homologous T-box transcription factors TBX2 and TBX3 are critical for embryonic development, and their overexpression in postnatal tissues contributes to a wide range of malignancies, including melanoma and rhabdomyosarcoma. Importantly, when TBX2 and TBX3 are depleted in cancers where they are overexpressed, the malignant phenotype is inhibited, and they have therefore been regarded as druggable targets. However, the time and costs associated with de novo drug development are challenging and result in drugs that are costly, especially for patients in low- and middle-income countries. In the current study, we therefore combined a targeted and drug repurposing approach to identify drugs that are expected to be more efficacious and cost-effective with significantly reduced side effects. METHODS: A high-throughput cell-based immunofluorescence screen was performed to identify drugs in the Pharmakon 1600 drug library that can negatively regulate TBX2 and/or TBX3 levels. "Hit" drugs were validated for their effect on TBX2/TBX3 levels and cytotoxicity in TBX2/TBX3-dependent melanoma and rhabdomyosarcoma cells. To this end, immunofluorescence, western blotting, quantitative real-time PCR, and MTT cell viability assays were performed. RESULTS: Niclosamide, piroctone olamine, and pyrvinium pamoate, were identified as TBX2 and/or TBX3-targeting drugs, and they exhibited cytotoxicity in a TBX2/TBX3-dependent manner. Furthermore, these "Hit" drugs were shown to induce senescence and/or apoptosis. CONCLUSIONS: Niclosamide, piroctone olamine, and pyrvinium pamoate are promising, cost-effective therapeutic agents for the treatment of TBX2/TBX3-dependent cancers.
MR1-ligand cross-linking identifies vitamin B6 metabolites as TCR-reactive antigens.
Major histocompatibility complex class I-related protein 1 (MR1) plays a central role in the immune recognition of infected cells and can mediate T cell detection of cancer. Knowledge of the nature of the ligands presented by MR1 is still sparse and has been limited by a lack of efficient approaches for MR1 ligand discovery. Here, we present a cross-linking strategy to investigate Schiff base-bound MR1 ligands. Our methodology employs reductive amination to stabilize the labile Schiff base bond between MR1 and its ligand, allowing for the detection of ligands as covalent MR1 adducts by mass spectrometry-based proteomics. We apply our approach to identifying vitamin B6 vitamers pyridoxal and pyridoxal 5'-phosphate (PLP) as MR1 ligands and show that both compounds are recognized by T cells expressing either A-F7, a mucosal-associated invariant T (MAIT) cell T cell receptor (TCR), or MC.7.G5, an MR1-restricted TCR reported to recognize cancer cells, highlighting them as immunogenic MR1 ligands.
TDP-43 pathology is associated with divergent protein profiles in ALS brain and spinal cord.
Neuronal and glial cytoplasmic inclusions positive for TAR DNA-binding protein 43 (TDP-43) are the defining pathological hallmark of 97% of amyotrophic lateral sclerosis (ALS) and 50% of frontotemporal dementia (FTD). The ALS-FTD clinicopathological spectrum variably involves cortical and spinal anterior horn cell pathology. The broader protein composition of these inclusions is of major importance to understanding pathogenesis, clinical heterogeneity and biomarker development. This study examined the proteome associated with TDP-43 inclusions in ALS, using mass spectrometry-based proteomic analysis of spinal cord and cerebral cortex from donors with phosphoTDP-43 positive ALS (n = 16), alpha-synuclein positive Parkinson's disease (PD, n = 8), phosphotau and beta-amyloid positive Alzheimer's disease (AD, n = 8) and age matched non-neurological controls (n = 8), comparing ALS with non-ALS conditions, spinal cord with cerebral cortex samples, and detergent-soluble with -insoluble fractions. Increased abundance of TDP-43 in the detergent-insoluble fraction of ALS cortex and spinal cord tissue confirmed disease-specific protein enrichment by serial fractionation. The most striking alterations between ALS and other conditions were found in the detergent-insoluble fraction of spinal cord, with predominant enrichment of endosomal and extracellular vesicle pathways. In the cortex mitochondrial membrane/envelope and ion transmembrane transport pathways were enriched in the detergent-insoluble fraction. RNA/DNA metabolic processes (in spinal cord) versus mitochondrial and synaptic protein pathways (in cortex) were upregulated in the detergent-soluble fraction of ALS cases and downregulated in the insoluble protein fraction. Whilst motor cortex and spinal cord may not optimally reflect disease-specific pathways in AD, in PD a significant enrichment of alpha-synuclein in the detergent-insoluble fraction of spinal cord was found. Among proteins concordantly elevated in the detergent-insoluble fractions of spinal cord and cortex, there was greater representation of proteins encoded by ALS-associated genes, specifically Cu/Zn superoxide dismutase 1, valosin containing protein and TDP-43 (odds ratio 16.34, p = 0.002). No significant increase in TDP-43 interacting proteins was observed in either detergent-soluble or -insoluble fractions. Together, this study shows a divergence in the composition of proteins associated with TDP-43 positive detergent-insoluble inclusions between spinal cord and cerebral cortex. A common upregulation of proteins encoded by ALS-causing genes implicates their role in the pathogenesis of the ALS-FTD spectrum of diseases beyond TDP-43. Data are available via ProteomeXchange with identifier PXD067060.
Fragment-Based Drug Discovery of Novel High-affinity, Selective, and Anti-inflammatory Inhibitors of the Keap1-Nrf2 Protein-Protein Interaction.
Activating the cytoprotective response of nuclear factor erythroid 2-related factor 2 (Nrf2) can reduce oxidative stress and inflammation. A promising strategy is to inhibit the protein-protein interaction between Kelch-like ECH-associated protein 1 (Keap1) and Nrf2 using noncovalent compounds that target the Keap1 Kelch domain. These compounds may be more specific than covalent Keap1-reacting Nrf2 activators. However, the development of drug-like noncovalent Keap1-Nrf2 inhibitors faces challenges due to the size and polarity of the Kelch binding pocket. Here, we present a new series of noncovalent Keap1-Nrf2 inhibitors developed from a weak fragment hit identified by crystallographic screening. A two-step growing strategy and optimization guided by several X-ray cocrystal structures led to compounds with low nanomolar affinities and complete selectivity for Keap1 in a panel of homologous Kelch domains. In cells, compounds 24 and 28 potently activated the expression of Nrf2-controlled genes and showed anti-inflammatory effects by downregulating NLRP3 inflammasome and STING signalling activation. RNA sequencing revealed activation of cytoprotective pathways and a different profile from typical covalent Nrf2 activators. This work highlights the potential of fragment-based drug discovery for challenging targets like Keap1 and introduces novel Keap1-Nrf2 inhibitors as chemical probes and drug leads.
Targeting G1-S-checkpoint-compromised cancers with cyclin A/B RxL inhibitors.
Small-cell lung cancers (SCLCs) contain near-universal loss-of-function mutations in RB1 and TP53, compromising the G1-S checkpoint and leading to dysregulated E2F activity1. Other cancers similarly disrupt the G1-S checkpoint through loss of CDKN2A or amplification of cyclin D or cyclin E, also resulting in excessive E2F activity2,3. Although E2F activation is essential for cell cycle progression, hyperactivation promotes apoptosis4-9, presenting a therapeutic vulnerability. Cyclin proteins use a conserved hydrophobic patch to bind to substrates bearing short linear RxL motifs10-13. Cyclin A represses E2F through an RxL-dependent interaction10,14, which, when disrupted, hyperactivates E2F15. However, this substrate interface has remained difficult to target. Here we developed cell-permeable, orally bioavailable macrocyclic peptides that inhibit RxL-mediated interactions of cyclins with their substrates. Dual inhibitors of cyclin A and cyclin B RxL motifs (cyclin A/Bi) selectively kill SCLC cells and other cancer cells with high E2F activity. Genetic screens revealed that cyclin A/Bi induces apoptosis through cyclin B- and CDK2-dependent spindle assembly checkpoint activation. Mechanistically, cyclin A/Bi hyperactivates E2F and cyclin B by blocking cyclin A-E2F and cyclin B-MYT1 RxL interactions. Notably, cyclin A/Bi promoted the formation of neomorphic cyclin B-CDK2 complexes, which drive spindle assembly checkpoint activation and mitotic cell death. Finally, orally administered cyclin A/Bi showed robust anti-tumour activity in chemotherapy-resistant SCLC patient-derived xenografts. These findings reveal gain-of-function mechanisms through which cyclin A/Bi triggers apoptosis and support their development for E2F-driven cancers.
SLC45A4 is a pain gene encoding a neuronal polyamine transporter.
Polyamines are regulatory metabolites with key roles in transcription, translation, cell signalling and autophagy1. They are implicated in multiple neurological disorders, including stroke, epilepsy and neurodegeneration, and can regulate neuronal excitability through interactions with ion channels2. Polyamines have been linked to pain, showing altered levels in human persistent pain states and modulation of pain behaviour in animal models3. However, the systems governing polyamine transport within the nervous system remain unclear. Here, undertaking a genome-wide association study (GWAS) of chronic pain intensity in the UK Biobank (UKB), we found a significant association between pain intensity and variants mapping to the SLC45A4 gene locus. In the mouse nervous system, Slc45a4 expression is enriched in all sensory neuron subtypes within the dorsal root ganglion, including nociceptors. Cell-based assays show that SLC45A4 is a selective plasma membrane polyamine transporter, and the cryo-electron microscopy (cryo-EM) structure reveals a regulatory domain and basis for polyamine recognition. Mice lacking SLC45A4 show normal mechanosensitivity but reduced sensitivity to noxious heat- and algogen-induced tonic pain that is associated with reduced excitability of C-polymodal nociceptors. Our findings therefore establish a role for neuronal polyamine transport in pain perception and identify a target for therapeutic intervention in pain treatment.
Covalently constrained 'Di-Gembodies' enable parallel structure solutions by cryo-EM.
Whilst cryo-electron microscopy(cryo-EM) has become a routine methodology in structural biology, obtaining high-resolution cryo-EM structures of small proteins (<100 kDa) and increasing overall throughput remain challenging. One approach to augment protein size and improve particle alignment involves the use of binding proteins or protein-based scaffolds. However, a given imaging scaffold or linking module may prove inadequate for structure solution and availability of such scaffolds remains limited. Here, we describe a strategy that exploits covalent dimerization of nanobodies to trap an engineered, predisposed nanobody-to-nanobody interface, giving Di-Gembodies as modular constructs created in homomeric and heteromeric forms. By exploiting side-chain-to-side-chain assembly, they can simultaneously display two copies of the same or two distinct proteins through a subunit interface that provides sufficient constraint required for cryo-EM structure determination. We validate this method with multiple soluble and membrane structural targets, down to 14 kDa, demonstrating a flexible and scalable platform for expanded protein structure determination.
A systems-based approach to uterine fibroids identifies differential splicing associated with abnormal uterine bleeding.
BACKGROUND: Uterine fibroids (UFs), benign tumours prevalent in up to 80% of women of reproductive age, are associated with significant morbidity, including abnormal uterine bleeding, pain and infertility. Despite identification of key genomic alterations in MED12 and HMGA2, the pathogenic mechanisms underlying UFs and heavy menstrual bleeding (HMB) remain poorly understood. METHODS: To correlate systematically genetic, transcriptional and proteomic phenotypes, we conducted an integrative multi-omic approach utilising targeted DNA sequencing, RNA sequencing and proteomic methodologies, encompassing fibroid, myometrium, and endometrium tissues from 91 patients. RESULTS: In addition to confirming the presence of MED12 mutations, we identify variants in AHR and COL4A6. Multi-omic analysis of endometrium identifies latent factors that correlate with HMB and fibroid presence with driver mutations of MED12, AHR, and COL4A6, which are associated with pathways involved in angiogenesis, extracellular matrix organisation and RNA splicing. We propose a model, supported by in vivo evidence, where altered signalling of MED12-mutated fibroids influences RNA transcript isoform expression in endometrium, potentially leading to abnormal uterine bleeding. CONCLUSIONS: This study presents a comprehensive integrative approach, revealing that genetic alterations in UF may influence endometrial function via signalling impacts on the RNA splicing mechanism. Our findings advance the understanding of complex molecular pathways in UF pathogenesis and UF-associated endometrial dysfunction, offering insights for targeted therapeutic development.
Tetrahydropyrazolopyridinones as a Novel Class of Potent and Highly Selective LIMK Inhibitors.
LIMKs are serine/threonine and tyrosine kinases that play critical roles in regulating actin filament turnover, affecting key cellular processes such as cytoskeletal remodeling, proliferation and migration. Aberrant LIMK overactivation has been implicated in several diseases, including cancers and neurodegenerative disorders. Understanding the precise molecular mechanisms by which LIMKs modulate actin cytoskeletal dynamics necessitates highly potent and selective LIMK pharmacological inhibitors. We report the discovery of a novel class of allosteric dual-LIMK1/2 inhibitors based on the tetrahydropyrazolopyridinone scaffold. Using structure-based drug design, we identified MDI-117740 (69) as a highly potent dual-LIMK1/2 inhibitor with significantly improved DMPK properties compared to prior inhibitors, suitable for in vivo evaluation. Importantly, 69 has very low kinome promiscuity, including former off-target RIPK1, representing the most selective LIMK inhibitor reported to date. Such a chemical probe will enable researchers to selectively dissect LIMK activation under physiological or disease conditions and spur translation of new therapeutics targeting LIMK pathologies.
Pleural fluid proteomics from patients with pleural infection shows signatures of diverse neutrophilic responses: The Oxford Pleural Infection Endotyping Study (TORPIDS-2).
BACKGROUND: Pleural infection is a complex disease with poor clinical outcomes and increasing incidence worldwide, yet its biological endotypes remain unknown. METHODS: We analysed 80 pleural fluid samples from the PILOT study, a prospective study on pleural infection, using unlabelled mass spectrometry. A total of 449 proteins were retained after filtering. Unsupervised hierarchical clustering and UMAP analyses were used to cluster samples and pathway analysis was performed to identify the biological processes. Protein signatures as identified by the pathway analysis were compared to microbiology as defined by 16S rRNA next generation sequencing. Spearman and exact Fischer's methods were used for correlation assessment. RESULTS: Higher neutrophil degranulation was correlated with increased glycolysis (OR=281, p<2.2E-16) and pentose phosphate activation (OR=371.45, p<2.2E-16). Samples dominated by Streptococcus pneumoniae exhibited higher neutrophil degranulation (OR=12.08, p=0.005), glycolysis (OR=11.4, p=0.006), and pentose phosphate activity (OR=12.82, p=0.004). On the other hand, samples dominated by anaerobes and Gram-negative bacteria exhibited lower neutrophil degranulation (OR=0.15, p=0.01, glycolysis (OR=0.14, p=0.01), and pentose phosphate activity (OR=0.07, p=0.001). Increased activity of the liver and retinoid X receptors (LXR-RXR) pathway was associated with lower risk of one-year mortality (OR=0.24, p=0.04). CONCLUSIONS: These findings suggest that pleural infection patients exhibit diverse responses of neutrophil mediated immunity, glycolysis, and pentose phosphate activation which are associated with microbiology. Therapeutic targeting of the LXR-RXR pathway with agonists is a possible treatment approach.
A new paradigm of islet adaptations in human pregnancy: insights from immunohistochemistry and proteomics.
Physiological changes during pregnancy support foetal growth, including adaptations in pancreatic islets to maintain glucose homeostasis. We investigate these adaptations using rare, high-quality pancreatic tissue from pregnant human donors and matched controls. We profile islets from pregnant donors using proteomics and assess α- and β-cell characteristics, as well as prolactin receptor and serotonin 2B receptor expression. Proteomic profiling of microdissected human islets identifies 7546 proteins but shows minimal differences in protein expression. In pregnancy, we show that islet area increases 1.9-fold, α- and β-cell areas increase 4.3- and 1.9-fold, driven by an increase in cell number rather than hypertrophy. Prolactin receptor expression is higher in α but not β cells, and serotonin 2B receptor is undetectable in β cells. Glucagon-like peptide-1 abundance increases 2.9-fold in α cells. These findings indicate that the molecular mechanisms driving pregnancy-induced islet adaptations in humans differ from those in mice, highlighting the need for human-based studies.
Protocol to profile spatially resolved NLRP3 inflammasome complexes using APEX2-based proximity labeling.
The NLRP3 inflammasome is a key multi-protein complex controlling inflammation, particularly interleukin-1β (IL-1β) production. Here, we present a protocol to profile spatially resolved NLRP3 inflammasome complexes using ascorbic peroxidase 2 (APEX2)-based proximity labeling combined with liquid chromatography-tandem mass spectrometry (LC-MS/MS). We describe steps for design and generation of the fusion construct, characterization of the stable FLAG-NLRP3-APEX2 expression cell line by western blotting/imaging, biotinylated proteome enrichment, and mass spectrometry analysis. For complete details on the use and execution of this protocol, please refer to Liang et al.1.
The dual ubiquitin binding mode of SPRTN secures rapid spatiotemporal proteolysis of DNA-protein crosslinks.
DNA-protein crosslinks (DPCs) are endogenous and chemotherapy-induced genotoxic DNA lesions and, if not repaired, lead to embryonic lethality, neurodegeneration, premature ageing, and cancer. DPCs are heavily polyubiquitinated, and the SPRTN protease and 26S proteasome emerged as two central enzymes for DPC proteolysis. The proteasome recognizes its substrates by their ubiquitination status. How SPRTN protease, an essential enzyme for DPC proteolysis, achieves specificity for DPCs is still not entirely clear. We found that the N-terminal SPRTN catalytic region (SprT) possesses a ubiquitin-binding domain that we named the Ubiquitin Interface of SprT Domain (USD). Using multiple biochemical, biophysical, and structural approaches, we reveal that USD binds ubiquitin chains in an avidity manner. SPRTN binding to ubiquitin chains via USD leads to ∼67-fold higher activation of SPRTN proteolysis towards polyubiquitinated DPCs than the unmodified DPCs. In contrast, the constitutive components of the replisome during unperturbed or translesional DNA synthesis, namely proliferating cell nuclear antigen (PCNA) or monoUb-PCNA, respectively, were poorly degraded, if at all, by SPRTN. This study reveals that the poly-ubiquitination of DPCs serves as the key signal for SPRTN's rapid proteolysis and determines its substrate specificity towards DPCs, rather than the replisome.
Driving Therapeutic Innovation in Neurodegenerative Disease with Hydrogen Deuterium eXchange Mass Spectrometry.
Human neurodegenerative conditions such as Parkinson's and Alzheimer's Disease are characterized by the formation and deposition of toxic protein species which exacerbate neuronal dysfunction, impacting the structure and function of the healthy brain. Deciphering the mechanisms underlying protein (mis)folding and aggregation is not only essential for a more coherent view of neurodegeneration, but also crucial for the development of novel therapeutics targeting this family of disorders. Key pathological drivers of neurodegeneration, such as alpha-synuclein and tau proteins, have traditionally proved extremely challenging to characterize structurally due to their intrinsic and widespread structural plasticity. Hydrogen-Deuterium eXchange Mass Spectrometry (HDX-MS) has emerged as a powerful tool to help circumvent this, owing to its ability to capture protein intrinsic disorder in solution, in addition to the transient structural conformations that typify protein aggregation pathways. This review brings together the most recent research where HDX-MS has shed light on mechanisms of neurodegeneration. We highlight how the technique has been successfully integrated into therapeutic development workflows targeting some of the most prevalent neurodegenerative diseases.
Amyloid-β disrupts APP-regulated protein aggregation and dissociation from recycling endosomal membranes.
Secretory proteins aggregate into non-soluble dense-core granules in recycling endosome-like compartments prior to regulated release. By contrast, aberrantly processed, secreted amyloid-β (Aβ) peptides derived from amyloid precursor protein (APP) form pathological extracellular amyloidogenic aggregations in late-stage Alzheimer's disease (AD). By examining living Drosophila prostate-like secondary cells, we show that both APP and Aβ peptides affect normal biogenesis of dense-core granules. These cells generate dense-core granules and secreted nanovesicles called Rab11-exosomes via evolutionarily conserved mechanisms within highly enlarged secretory compartments with recycling endosomal identity. The fly APP homologue, APP-like (APPL), associates with these vesicles and the compartmental limiting membrane, from where its extracellular domain modulates protein aggregation. Proteolytic release of this domain permits mini-aggregates to coalesce into a large central dense-core granule. Mutant Aβ expression disrupts this process and compartment motility, and increases aberrant lysosomal targeting, mirroring previously unexplained early-stage pathological events in AD. It also promotes cell-to-cell propagation of these endolysosomal defects, again phenocopying changes observed in AD. Our data therefore demonstrate physiological roles for APP in membrane-dependent protein aggregation, involving molecular mechanisms, which when disrupted by Aβ peptides, trigger Alzheimer's disease-relevant pathologies.