Project description:Dampening functional levels of the mitochondrial deubiquitylating enzyme USP30 has been suggested as an effective therapeutic strategy against neurodegenerative disorders such as Parkinson’s Disease. USP30 inhibition may counteract the deleterious effects of impaired turnover of damaged mitochondria which is inherent to both familial and sporadic forms of the disease. Small-molecule inhibitors targeting USP30 are currently in development, but little is known about their precise nature of binding to the protein. We have integrated biochemical and structural approaches to gain novel mechanistic insights into USP30 inhibition by a small-molecule benzosulfonamide containing compound, 39. Activity-based protein profiling (ABPP) mass spectrometry confirmed target engagement, the high selectivity, and potency of 39 for USP30 against 49 other deubiquitylating enzymes in a neuroblastoma cell line. In vitro characterization of 39 enzyme kinetics infers slow and tight binding behavior, which is comparable with features of covalent modification of USP30. Finally, we blended hydrogen-deuterium exchange mass spectrometry and computational docking to elucidate the molecular architecture and geometry of USP30 complex formation with 39, identifying structural rearrangements at the cleft of the USP30 thumb and palm subdomains. These studies suggest that 39 binds to the thumb-cleft that guides the ubiquitin C-terminus into the active site, thereby preventing ubiquitin binding and isopeptide bond cleavage, confirming its importance in the inhibitory process. Our data will pave the way for the design and development of next-generation inhibitors targeting USP30 and associated deubiquitinylases.

Project description:Inhibition of the mitochondrial deubiquitinating enzyme USP30 is neuroprotective and presents therapeutic opportunities for the treatment of idiopathic Parkinson’s Disease and mitophagy-related disorders. We have integrated structural and quantitative proteomics with biochemical assays to decipher the mode of action of covalent USP30 inhibition by a small molecule containing a cyanopyrrolidine reactive group, USP30-I-1. The inhibitor demonstrated high potency and selectivity for endogenous USP30 in neuroblastoma cells. Enzyme kinetics and Hydrogen Deuterium eXchange mass spectrometry (HDX-MS) infers that the inhibitor binds tightly to regions surrounding the USP30 catalytic cysteine and positions itself to form a binding pocket along the thumb and palm domains of the protein, thereby interfering its interaction with ubiquitin substrates. A comparison to a non-covalent USP30 inhibitor containing a benzosulfonamide scaffold revealed a slightly different binding mode closer to the active site Cys77, which may provide the molecular basis for improved selectivity towards USP30 against other members of the DUB enzyme family. Our results highlight advantages in developing covalent inhibitors, such as USP30-I-1, for targeting USP30 as treatment of disorders with impaired mitophagy.

Project description:Dampening functional levels of the mitochondrial deubiquitylating enzyme USP30 has been suggested as an effective therapeutic strategy against neurodegenerative disorders such as Parkinson’s Disease. USP30 inhibition may counteract the deleterious effects of impaired turnover of damaged mitochondria which is inherent to both familial and sporadic forms of the disease. Small-molecule inhibitors targeting USP30 are currently in development, but little is known about their precise nature of binding to the protein. We have integrated biochemical and structural approaches to gain novel mechanistic insights into USP30 inhibition by a small-molecule benzosulfonamide containing compound, 39. Activity-based protein profiling (ABPP) mass spectrometry confirmed target engagement, the high selectivity, and potency of 39 for USP30 against 49 other deubiquitylating enzymes in a neuroblastoma cell line. In vitro characterization of 39 enzyme kinetics infers slow and tight binding behavior, which is comparable with features of covalent modification of USP30. Finally, we blended hydrogen-deuterium exchange mass spectrometry and computational docking to elucidate the molecular architecture and geometry of USP30 complex formation with 39, identifying structural rearrangements at the cleft of the USP30 thumb and palm subdomains. These studies suggest that 39 binds to the thumb-palm cleft that guides the ubiquitin C-terminus into the active site, thereby preventing ubiquitin binding and isopeptide bond cleavage, and confirming its importance in the inhibitory process. Our data will pave the way for the design and development of next-generation inhibitors targeting USP30 and associated deubiquitinylases.

Project description:The mitochondrial deubiquitylase USP30 negatively regulates the selective autophagy of damaged mitochondria. It has been proposed as an actionable target to alleviate the loss of function of the mitophagy pathway governed by the Parkinson’s Disease associated genes PINK1 and PRKN. We present the characterisation of a N-cyano pyrrolidine derived compound, FT3967385, with high selectivity for USP30. The compound is well tolerated with no loss of total mitochondrial mass. We demonstrate that ubiquitylation of TOM20, a component of the outer mitochondrial membrane import machinery that directly interacts with USP30, represents a robust biomarker for both USP30 loss and inhibition. We have conducted proteomics analyses on a SHSY5Y neuroblastoma cell line model to directly compare the effects of genetic loss of USP30 with selective inhibition in an unbiased fashion. We have thereby identified a subset of ubiquitylation events consequent to mitochondrial depolarisation, that are USP30 sensitive. Within responsive elements of the ubiquitylome, several components of the outer mitochondrial membrane transport (TOM) complex are most prominent. Thus, our data support a model whereby USP30 can regulate the availability of ubiquitin at the specific site of mitochondrial PINK1 accumulation following membrane depolarisation. In this model, USP30 deubiquitylation of TOM complex components dampens the trigger that unleashes the Parkin-dependent amplification of mitochondrial ubiquitylation leading to mitophagy. Accordingly PINK1 generation of phospho-Ser65 Ubiquitin proceeds more rapidly and to a greater extent in cells either lacking USP30 or subject to USP30 inhibition.

Project description:Hepatitis B virus (HBV) core protein (HBc) plays many roles in the HBV life cycle such as regulation of transcription, RNA encapsidation, reverse transcription and viral release. To accomplish these functions, HBc interacts with many host proteins and undergoes different posttranslational modifications (PTMs). One of the most common PTM is ubiquitination that was shown to change function, stability, and intracellular localization of different viral proteins, but the role of HBc ubiquitination in the HBV life cycle remains unknown. Here, we found that HBc protein is posttranslationally modified through K29-linked ubiquitination. We performed a series of co-immunoprecipitation experiments with wild type HBc, lysine to arginine HBc mutants and wild type ubiquitin, single lysine to arginine ubiquitin mutants or single ubiquitin-accepting lysine constructs. We observed that HBc protein could be modified by ubiquitination in transfected as well as infected hepatoma cells. In addition, ubiquitination predominantly occurred on HBc lysine 7 and the preferred ubiquitin chain linkage was through ubiquitin-K29. Mass spectrometry (MS) analyses detected UBR5 as a potential E3 ubiquitin ligase involved in K29-linked ubiquitination. These findings emphasize that ubiquitination of HBc may play an important role in HBV life cycle.

Project description:Even though ubiquitination controls a plethora of cellular processes, modifications by linear polyubiquitin have so far only been linked with acquired and innate immunity, lymphocyte development and genotoxic stress response. Until now, a single E3 ligase complex (LUBAC), one specific deubiquitinase (Otulin) and a very few substrates have been identified. The existing methods for the study of lysine-based polyubiquitination are not suitable for the detection of linear polyubiquitin-modified proteins. Here, we present a novel approach to discovering linear polyubiquitin-modified substrates by combining lysine-less internally tagged ubiquitin (INT-Ub.7KR) with SILAC-based mass spectrometry. We applied our approach in TNFα-stimulated T-Rex HEK293T cells and afterwards validated newly identified linear polyubiquitin targets. Moreover, we demonstrated that linear polyubiquitination of the novel LUBAC substrate TRAF6 is essential for the NFkappaB signalling. Overall, we have established a powerful method for the detection of linear polyubiquitin substrates.

Project description:Transcriptomic studies revealed that hundreds of mRNAs show differential expression in the brains of sleeping versus awake rats, mice, flies, and sparrows. Although these results have offered clues regarding the molecular consequences of sleep and sleep loss, their functional significance thus far has been limited. This is because the previous studies pooled transcripts from all brain cells, including neurons and glia. In the following experiment, we studied the specific effects of sleep and wake conditions on glia cells of mouse cerebral cortex using the genetically targeted translating ribosome affinity purification (TRAP) methodology. We used bacterial artificial chromosome (BAC) transgenic mice expressing EGFP tagged ribosomal protein L10a in astrocytes which constitute a defined cellular population of the mouse brain. Using this approach, we could extract only the astrocytic mRNAs, and only those already committed to be translated into proteins (L10a is part of the translational machinery). Six mice for each vigilant state group (sleep (S), waking (W), and sleep deprivation (SD)) were considered. For each animal, cerebral cortex was dissected and immediately processed. Samples were immunoprecipitated to isolate astrocytes. The precipitated portion formed the bound sample (IP) containing astrocytes and the remaining part formed the unbound sample (UB) containing all the remaining cell types (neurons and other glia cells). Then, both IP and UB samples were processed and RNA was extracted. All the IP samples (n=18) were then hybridized to Affymetrix GeneChip Mouse Genome 430 2.0 arrays, while UB samples were pooled together in two biological replicates (UB1+UB2+UB3 and UB4+UB5+UB6) for each group (n=6 in total) and then hybridized to Affymetrix GeneChip Mouse Genome 430 2.0 arrays.

Project description:The mitochondrial deubiquitylase USP30 negatively regulates the selective autophagy of damaged mitochondria. It has been proposed as an actionable target to alleviate the loss of function of the mitophagy pathway governed by the Parkinson’s Disease associated genes PINK1 and PRKN. We present the characterisation of a N-cyano pyrrolidine derived compound, FT3967385, with high selectivity for USP30. The compound is well tolerated with no loss of total mitochondrial mass. We demonstrate that ubiquitylation of TOM20, a component of the outer mitochondrial membrane import machinery that directly interacts with USP30, represents a robust biomarker for both USP30 loss and inhibition. We have conducted proteomics analyses on a SHSY5Y neuroblastoma cell line model to directly compare the effects of genetic loss of USP30 with selective inhibition in an unbiased fashion. We have thereby identified a subset of ubiquitylation events consequent to mitochondrial depolarisation, that are USP30 sensitive. Within responsive elements of the ubiquitylome, several components of the outer mitochondrial membrane transport (TOM) complex are most prominent. Thus, our data support a model whereby USP30 can regulate the availability of ubiquitin at the specific site of mitochondrial PINK1 accumulation following membrane depolarisation. In this model, USP30 deubiquitylation of TOM complex components dampens the trigger that unleashes the Parkin-dependent amplification of mitochondrial ubiquitylation leading to mitophagy. Accordingly PINK1 generation of phospho-Ser65 Ubiquitin proceeds more rapidly and to a greater extent in cells either lacking USP30 or subject to USP30 inhibition.

Project description:Using Tet-inhibited expression of epitope-tagged H3.3 combined with ChIP-Seq we undertook genome-wide measurements of H3.3 dissociation rates across the ESC genome and examined the relationship between H3.3-nucleosome turnover and ESC-specific transcription factors, chromatin modifiers and epigenetic marks. To measure dissociation rates of H3.3, we utilized a TET-repressible ESC line, ES[MC1R(20)], with the expression cassette integrated at the ROSA26 locus. We transfected MC1R ESCs with HA/FLAG-tagged H3.3 controlled by tetracycline response elements. For ‘TET-OFF’ experiments, ESCs were cultured over several passages (weeks) on feeder cells in the absence of DOX and were subsequently passaged onto feeder-free plates prior to the inhibition of HA-H3.3 expression. To repress HA/FLAG-H3.3 expression we treated cells with 2 ?g/ml doxycycline hyclate before crosslinking with formaldehyde at various time points. Measurement of H3.3-HA enrichment over time-course was performed using two replicates of ChIP-seq experiments. As a control, input DNA sequencing was performed for every time point

Project description:Transcriptomic studies revealed that hundreds of mRNAs show differential expression in the brains of sleeping versus awake rats, mice, flies, and sparrows. Although these results have offered clues regarding the molecular consequences of sleep and sleep loss, their functional significance thus far has been limited. This is because the previous studies pooled transcripts from all brain cells, including neurons and glia. In the following experiment, we studied the specific effects of sleep and wake conditions on glia cells of mouse cerebral cortex using the genetically targeted translating ribosome affinity purification (TRAP) methodology. We used bacterial artificial chromosome (BAC) transgenic mice expressing EGFP tagged ribosomal protein L10a in oligodendrocytes which constitute a defined cellular population of the mouse brain. Using this approach, we could extract only the oligodendrocitic mRNAs, and only those already committed to be translated into proteins (L10a is part of the translational machinery). Six mice for each vigilant state group (sleep (S), waking (W), and sleep deprivation (SD)) were considered. For each animal, one forebrain sample was immediately processed. Samples were immunoprecipitated to isolate oligodendrocytes. The precipitated portion formed the bound sample (IP) containing olidodendrocytes and the remaining part formed the unbound sample (UB) containing all the remaining cell types (neurons and other glia cells). Then, both IP and UB samples were processed and RNA was extracted.