Project description:Influenza A virus (IAV) is a segmented negative-sense RNA virus and is the cause of major global epidemics and pandemics. The replication of IAV is complex, involving both transcription and replication, during which three distinct RNA species, namely mRNA, cRNA, and vRNA are generated for all eight genome segments. While understanding IAV replication kinetics is important for drug development and improving vaccine production, current methods for studying IAV kinetics has been limited by the ability to detect all three different RNA species in a scalable manner. Here were report the development of a novel pipeline using total stranded RNA-Seq, named Influenza Virus Enumerator of RNA Transcripts (InVERT) which allows for the simultaneous quantification of all three RNA species of IAV. Using InVERT provides a full landscape of the IAV replication kinetics, in which we found that different groups of viral genes followed different traits of kinetics. During a cycle of infection, the RNA-dependent RNA Polymerase (RdRP) produced more vRNA than mRNA while some other genes (NP, NS, HA) consistently make more mRNA than vRNA. vRNA expression levels do not correlate with the cRNA expression, suggesting complex regulations of vRNA synthesis. Furthermore, by studying the kinetics of a virus lacking the capacity to generate new polymerase complexes, we found evidence that further supports the model that cRNA synthesis requires newly synthesized RdRP and that incoming RdRP can only generate mRNA.

Project description:Due to the RNA nature of their genomes, influenza viruses have to utilize many RNA-binding proteins (RBPs) of both viral and host origin, for their replication. To uncover the comprehensive vRNA-host protein interactions, we performed affinity purification coupled with mass spectrometry (AP-MS) analysis of influenza vRNA complexes. The eight vRNA segments of H7N9 were transcribed and individually labeled with biotin in vitro and incubated with IAV virus-infected THP-1 cells, and vRNA complexes were enriched streptavidin magnetic beads and analyzed by mass spectrometry

Project description:Post-translational modification of proteins by ubiquitin (UQ) and UQ-like modifiers is emerging as a central pathway in DNA replication. We previously showed that chromatin in the vicinity of replisomes is rich in SUMO and depleted in UQ, whereas an opposite pattern is observed in mature chromatin. How this SUMO-rich/UQ-low environment is maintained at replisomes is not known. Here we identify USP7 as a SUMO deubiquitinase that localizes to replication forks and is essential for DNA replication. By acting on SUMO and SUMOylated proteins, USP7 prevents their ubiquitination. Chemical inhibition or genetic deletion of USP7 leads to the accumulation of UQ on SUMOylated proteins, which are displaced from the replisomes. Our findings provide a model to explain the differential accumulation of SUMO and UQ in replication forks versus mature chromatin, and identify an essential role of USP7 that should be taken into account for the use of USP7 inhibitors as anticancer agents.

Project description:Assembly of infectious influenza A viruses (IAV) is a complex process involving transport from the nucleus to the plasma membrane. Rab11A containing recycling endosomes have been identified as a platform for intracellular transport of viral RNA (vRNA). Using high spatiotemporal resolution light-sheet microscopy (~1.4 volumes/s, 330 nm isotropic spatial resolution), we quantify Rab11A and vRNA movement in live cells during IAV infection. Here we report that IAV infection decreases speed and increases arrest of Rab11A. Unexpectedly, infection with RSV alters Rab11A motion in a manner opposite to IAV, suggesting that Rab11A is a common host component that is differentially manipulated by respiratory RNA viruses. Using two-color imaging we demonstrate co-transport between Rab11A and IAV vRNA in infected cells and provide direct evidence that vRNA-associated Rab11A have altered transport. The mechanism of altered Rab11A movement is likely related to a decrease in dynein motors bound to Rab11A vesicles during IAV infection.

Project description:We developed a strategy that allows the identification of NEDP1 dependent NEDDylation sites under endogenous expression of wild type NEDD8. We combined the use of anti-diGly antibodies that recognise both ubiquitin and NEDD8 modified peptides upon trypsin digestion with short treatment of cells with the ubiquitin E1 inhibitor MLN7243 (UAEi), that dramatically reduces ubiquitin but not NEDD8 modification. By eliminating the majority of ubiquitin-derived diGly peptides upon MLN7243 treatment, we would be able to quantify NEDP1 dependent diGly peptides. Extracts from parental and NEDP1 knockout HCT116 cells both treated with UAEi were used for the isolation of diGly modified peptides and mass spectrometry analysis.

Project description:The ubiquitin-proteasome system (UPS) is essential for replication of Orthopoxviruses (OPV) like vaccinia and cowpox virus (CPXV). Although several proteome studies identified ubiquitin as part of OPV particles, distinct modification sites are largely unknown. Moreover, the UPS plays a key role in poxvirus core uncoating but the underlying mechanisms are still elusive. In the presented study we show that impairment of CPXV replication by proteasome inhibition is caused by a lack of uncoating which can be observed by electron microscopy. These results suggest, that UPS-dependent degradation of viral core proteins is the mechanism underlying CPXV genome uncoating. To proof this hypothesis we analyzed the mature virion ubiquitinome of CPXV using mass spectrometry (MS). We elucidated 137 conserved ubiquitination sites in 54 viral proteins among five CPXV strains verifying ubiquitin is a major poxvirus modification. Structural core proteins were massively ubiquitinated and virions contained large amounts of K48-linked polyubiquitin supporting the hypothesis. Hence, we aimed to show the proteasome-dependent degradation of CPXV core proteins in infected HeLa cells. However, using MS-based quantitative analysis of ubiquitinated virus proteins early in infection we were not able to show the degradation of viral core proteins. Instead, our results revealed the proteasomal degradation of viral proteins associated with the formation of prereplication sites early in infection.

Project description:The level of ubiquitin protein of the heart of DICAR+/- compared with wild type

Project description:A polyubiquitin chain can adopt a variety of shapes, depending on how the ubiquitin monomers are joined. However, the relevance of linkage for the signaling functions of polyubiquitin chains is often poorly understood because of our inability to control or manipulate this parameter in vivo. Here we present a strategy for reprogramming polyubiquitin chain linkage by means of tailor-made, linkage- and substrate-selective ubiquitin ligases. Using the polyubiquitylation of the budding yeast replication factor PCNA in response to DNA damage as a model case, we show that altering the features of a polyubiquitin chain in vivo canchange the fate of the modified substrate. We also provide evidence for redundancy betweendistinct, but structurally similar linkages, and we demonstrate by proof-of-principle experiments that the method can be generalized to targets beyond PCNA. Our study illustrates apromising approach towards the in vivo analysis of polyubiquitin signaling.

Project description:We describe ubiquitomics and proteomics analysis of porcine articular cartilage post mechanical injury. Analysis showed ubiquitin peptides differentially enriched post injury compared to non injured controls.

Project description:mTOR is a central regulator of mammalian metabolism and physiology. Aberrant hyperactivation of this pathway promotes tumor growth and metastasis and drives tumor resistance to chemotherapy and cancer drugs, making mTOR an attractive cancer therapeutic target. mTOR inhibitors have been approved to treat cancer, however, the basis for drug sensitivity remains poorly understood. Here, whole exome sequencing of three chromophobe renal cell carcinoma (chRCC) patients with exceptional mTOR inhibitor sensitivity, uncovered USP9X deubiquitinase as the only mutated gene shared by the tumors. The clonal characteristics of the mutations, revealed by studying multiple patients’ primary and metastatic samples along the years, together with the low USP9X mutation rate in unselected chRCC series, reinforced a causal link between USP9X and mTOR inhibitor sensitivity. Rapamycin treatment of USP9X depleted HeLa and renal cancer 786-O cells and the pharmacological inhibition of USP9X, confirmed a crucial role of this protein in the patients’ sensitivity to mTOR inhibition. As no direct effect of USP9X in mTORC1 was detected, we performed ubiquitylome analyses that identified p62 as a direct USP9X target. Increased p62 ubiquitination and an augmented rapamycin effect upon bortezomib treatment, together with p62 and LC3 immunofluorescence assays, suggested that dysregulated autophagy in USP9X depleted cells can synergize with mTOR inhibitors. In summary, here we show that USP9X constitutes a potential novel marker of sensitivity to mTOR inhibitors in chRCC patients and represents a clinically exploitable strategy that could increase sensitivity to these drugs