Structural and functional features of central nervous system lymphatic vessels
One of the characteristics of the CNS is the lack of a classical lymphatic drainage system. Although it is now accepted that the CNS undergoes constant immune surveillance that takes place within the meningeal compartment1–3, the mechanisms governing the entrance and exit of immune cells from the CNS remain poorly understood4–6. In searching for T cell gateways into and out of the meninges, we discovered functional lymphatic vessels lining the dural sinuses. These structures express all of the molecular hallmarks of lymphatic endothelial cells, are able to carry both fluid and immune cells from the CSF, and are connected to the deep cervical lymph nodes. The unique location of these vessels may have impeded their discovery to date, thereby contributing to the long-held concept of the absence of lymphatic vasculature in the CNS. The discovery of the CNS lymphatic system may call for a reassessment of basic assumptions in neuroimmunology and shed new light on the etiology of neuroinflammatory and neurodegenerative diseases associated with immune system dysfunction.
Interaction of pathogens with cells of the immune system results in activation of inflammatory gene expression. This response, while vital for immune defence, is frequently deleterious to the host due to the exaggerated production of inflammatory proteins. The scope of inflammatory responses reflects the activation state of signalling proteins upstream of inflammatory genes as well as signal-induced assembly of nuclear chromatin complexes that support mRNA expression1–4. Recognition of post-translationally modified histones by nuclear proteins that initiate mRNA transcription and support mRNA elongation is a critical step in the regulation of gene expression5–10. Here we present a novel pharmacological approach that targets inflammatory gene expression by interfering with the recognition of acetylated histones by the Bromodomain and Extra Terminal domain (BET) family of proteins. We describe a synthetic compound (I-BET) that by “mimicking” acetylated histones disrupts chromatin complexes responsible for the expression of key inflammatory genes in activated macrophages and confers protection against LPS-induced endotoxic shock and bacteria-induced sepsis. Our findings suggest that synthetic compounds specifically targeting proteins that recognize post-translationally modified histones can serve as a new generation of immunomodulatory drugs.
Epigenetic regulation of gene expression is a dynamic and reversible process that establishes normal cellular phenotypes but also contributes to human diseases. At the molecular level, epigenetic regulation involves hierarchical covalent modification of DNA and the proteins that package DNA, such as histones. Here, we review the key protein families that mediate epigenetic signalling through the acetylation and methylation of histones, including histone deacetylases, protein methyltransferases, lysine demethylases, bromodomain-containing proteins and proteins that bind to methylated histones. These protein families are emerging as druggable classes of enzymes and druggable classes of protein-protein interaction domains. In this article, we discuss the known links with disease, basic molecular mechanisms of action and recent progress in the pharmacological modulation of each class of proteins.
In 2015, as part of the Reproducibility Project: Cancer Biology, we published a Registered Report (Fung et al., 2015), that described how we intended to replicate selected experiments from the paper "Inhibition of BET recruitment to chromatin as an effective treatment for MLL-fusion leukaemia" (Dawson et al.
The jumonji (JMJ) family of histone demethylases are Fe2+- and α-ketoglutarate-dependent oxygenases that are essential components of regulatory transcriptional chromatin complexes1–4. These enzymes demethylate lysine residues in histones in a methylation-state and sequence-specific context5. Considerable effort has been devoted to gaining a mechanistic understanding of the roles of histone lysine demethylases in eukaryotic transcription, genome integrity and epigenetic inheritance2,4,6, as well as in development, physiology and disease3,7. However, because of the absence of any selective inhibitors, the relevance of the demethylase activity of JMJ enzymes in regulating cellular responses remains poorly understood. Here we present a structure-guided small-molecule and chemoproteomics approach to elucidating the functional role of the H3K27me3-specific demethylase subfamily (KDM6 subfamily members JMJD3 and UTX)8. The liganded structures of human and mouse JMJD3 provide novel insight into the specificity determinants for cofactor, substrate and inhibitor recognition by the KDM6 subfamily of demethylases. We exploited these structural features to generate the first small-molecule catalytic site inhibitor that is selective for the H3K27me3-specific JMJ subfamily. We demonstrate that this inhibitor binds in a novel manner and reduces lipopolysaccharide-induced proinflammatory cytokine production by human primary macrophages, a process that depends on both JMJD3 and UTX. Our results resolve the ambiguity associated with the catalytic function of H3K27-specific JMJs in regulating disease-relevant inflammatory responses and provide encouragement for designing small-molecule inhibitors to allow selective pharmacological intervention across the JMJ family.
We have developed an experimental strategy to monitor protein interactions in a cell with a high degree of selectivity and sensitivity. A transcription factor is tethered to a membrane-bound receptor with a linker that contains a cleavage site for a specific protease. Activation of the receptor recruits a signaling protein fused to the protease that then cleaves and releases the transcription factor to activate reporter genes in the nucleus. This strategy converts a transient interaction into a stable and amplifiable reporter gene signal to record the activation of a receptor without interference from endogenous signaling pathways. We have developed this assay for three classes of receptors: G protein-coupled receptors, receptor tyrosine kinases, and steroid hormone receptors. Finally, we use the assay to identify a ligand for the orphan receptor GPR1, suggesting a role for this receptor in the regulation of inflammation.cellular assays ͉ G protein-coupled receptor ͉ protein interaction A ll cells have evolved mechanisms to respond to rapid changes in the environment. Extracellular signals are detected by transmembrane receptors that translate binding into intracellular signaling events. Most signaling systems that respond to environmental cues exhibit adaptation mechanisms that afford the cell a facile response to rapid changes in their surroundings. Mechanisms to assure the rapid but transient response to environmental cues are of obvious advantage to the cell but seriously limit most assays for receptor function. We have genetically modified receptors such that transient responses to ligand result in the stable transcription of a reporter gene. The transformation of a transient intracellular response to a stable amplifiable readout provides a sensitive and quantitative assay for receptor function.We have developed an assay for receptor activation and more generally for protein-protein interaction that involves the fusion of a membrane receptor with a transcriptional activator. The membrane-bound receptor and transcription factor sequences are separated by a cleavage site for a highly specific viral protease. A second gene encodes a fusion of the viral protease with a cellular protein that interacts only with activated receptor. Ligand binding to the receptor will stimulate this proteinprotein interaction, recruiting the protease to its cleavage site. Site-specific cleavage will release the transcriptional regulator that can now enter the nucleus and activate reporter genes. Recently, a similar principle, based on the complementation of split tobacco etch virus (TEV) protease fragments, has been used to monitor protein interactions (1). Our experimental scheme derives conceptually from the mechanism of action of the Notch receptor in which ligand binding elicits proteolytic cleavage events in the receptor to release a Notch intracellular domain that translocates to the nucleus and modulates transcription of downstream target genes (2, 3) (Fig. 1A).The assay we have developed relies solely on exogenous genes in...
55 Recurrent chromosomal translocations involving the mixed lineage leukaemia (MLL) gene initiate aggressive forms of leukaemia, which confer a poor prognosis and are often refractory to conventional therapies. Recent efforts have begun to unravel the molecular pathogenesis of these malignancies. Several groups have demonstrated that MLL-fusions associate with two macromolecular chromatin complexes; the polymerase associated factor (PAFc) complex, which interacts with the N-terminal domain of MLL, a portion of the protein that is retained in all the described fusions, or the super elongation complex (SEC), via interaction with the C-terminal fusion partner. These complexes play an integral role in regulating transcriptional elongation and this function appears to be aberrantly co-opted by the MLL-fusions to initiate and perpetuate transcriptional programmes that culminate in leukaemia. In this study we used a systematic global proteomic survey incorporating quantitative mass spectrometry to demonstrate that MLL-fusions, as part of SEC and PAFc complexes, are associated with the BET family of acetyl lysine recognition chromatin “adaptor” proteins. These data provided the basis for therapeutic intervention in MLL-fusion leukaemia, via the displacement of the BET family of proteins from chromatin. Targeting the BET proteins to alter aberrant transcriptional elongation has recently been demonstrated to be possible using small molecule inhibitors that selectively bind the tandem bromodomain at the amino-terminus of the ubiquitously expressed BET proteins (BRD2/BRD3/BRD4). We developed a novel class of potent small molecule inhibitors to the BET family, which is chemically distinct to previously published BET-inhibitors. We then used this new compound (I-BET151) to demonstrate its profound and selective efficacy against human MLL-fusion leukaemic cell lines in liquid culture as well as clonogenic assays in methylcellulose. We also establish that primary murine progenitors retrovirally transformed with MLL-ENL and MLL-AF9 are equally susceptible to treatment with I-BET151. We show that the main phenotypic consequence of BET inhibition in MLL fusion leukaemia is a dramatic early induction of cell cycle arrest and apoptosis. Global gene-expression profiling, following I-BET151 treatment in two different human MLL-fusion leukaemia cell lines (expressing MLL-AF4 and MLL-AF9), highlights a common differentially expressed gene signature that accounts for this phenotype. Importantly, chromatin immunoprecipitation analyses at direct MLL target genes including BCL2, C-MYC and CDK6, indicate that I-BET151 selectively inhibits the recruitment of BET family members BRD3/BRD4, and SEC and PAFc components. These events result in the inefficient phosphorylation and release of paused POL-II from the TSS of these genes providing mechanistic insight into the mode of action of I-BET151 in MLL-fusion leukaemia. We subsequently established the therapeutic efficacy of I-BET151 in vivo by demonstrating dramatic disease control in murine models of MLL-AF4 and MLL-AF9 leukaemia. Finally, we also demonstrate that I-BET151 accelerates apoptosis in primary leukaemic cells from a large number of patients with various MLL-fusion leukaemias, by affecting a similar transcription programme to that identified in the human leukaemic cell lines. Importantly, we also demonstrate that I-BET151 significantly reduces the clonogenic potential of isolated primary leukaemic stem cells, suggesting that disease eradication may be possible. These data highlight a new paradigm for drug discovery targeting the protein-protein interactions of chromatin-associated proteins. We demonstrate that small molecules that perturb the interaction of BRD3/4 with chromatin have therapeutic potential in MLL fusion leukaemias and moreover, we provide the molecular mechanism to account for this therapeutic efficacy. Finally, our results emphasize an emerging role for targeting aberrant transcriptional elongation in oncogenesis. Disclosures: Prinjha: GSK: Employment. Chung:GSK: Employment. Lugo:GSK: Employment. Beinke:GSK: Employment. Soden:GSK: Employment. Mirguet:GSK: Employment. Jeffrey:GSK: Employment. Lee:GSK: Employment. Kouzarides:GSK: Consultancy.
Immune dysfunction is commonly associated with several neurological and mental disorders. Although the mechanisms by which peripheral immunity may influence neuronal function are largely unknown, recent findings implicate meningeal immunity influencing behavior, such as spatial learning and memory1. Here we show that meningeal immunity is also critical for social behavior; mice deficient in adaptive immunity exhibit social deficits and hyper-connectivity of fronto-cortical brain regions. Associations between rodent transcriptomes from brain and cellular transcriptomes in response to T cell–derived cytokines suggest a strong interaction between social behavior and interferon-gamma (IFN-γ) driven responses. Concordantly, we demonstrate that inhibitory neurons respond to IFN-γ and increase GABAergic currents in projection neurons, suggesting that IFN-γ is a molecular link between meningeal immunity and neural circuits recruited for social behavior. Meta-analysis on the transcriptomes of a range of organisms revealed that rodents, fish, and flies elevate IFN-γ/JAK-STAT–dependent gene signatures in a social context, suggesting that the IFN-γ signaling pathway could mediate a co-evolutionary link between social/aggregation behavior and an efficient anti-pathogen response. This study implicates adaptive immune dysfunction, in particular IFN-γ, in disorders characterized by social dysfunction and suggests a co-evolutionary link between social behavior and an anti-pathogen immune response driven by IFN-γ signaling.
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