Project description:Accurate annotation of regulatory RNAs is a complex task but nevertheless essential as sRNA molecular and functional studies ensue from it. Several formerly considered small RNAs (sRNA) are now known to be parts of UTR transcripts. In light of experimental data, we review hundreds of Staphylococcus aureus putative regulatory RNAs. We pinpoint those that are likely acting in trans and are not expressed from the opposite strand of a coding gene. We conclude that HG003, a NCTC8325 derivative strain, has about 50 bona fide sRNAs, indicating that these RNAs are less numerous than commonly stated.

Project description:CD74-NRG1 fusion as an bona fide oncogene

Project description:Bacterial regulatory RNAs have been extensively studied for over a decade, and are progressively being integrated into the complex genetic regulatory network. Transcriptomic arrays, recent deep-sequencing data and bioinformatics suggest that bacterial genomes produce hundreds of regulatory RNAs. However, while some have been authenticated, the existence of the others varies according to strains and growth conditions, and their detection fluctuates with the methodologies used for data acquisition and interpretation. For example, several small RNA (sRNA) candidates are now known to be parts of UTR transcripts. Accurate annotation of regulatory RNAs is a complex task essential for molecular and functional studies. We defined bona fide sRNAs as those that (i) likely act in trans and (ii) are not expressed from the opposite strand of a coding gene. Using published data and our own RNA-seq data, we reviewed hundreds of Staphylococcus aureus putative regulatory RNAs using the DETR'PROK computational pipeline and visual inspection of expression data, addressing the question of which transcriptional signals correspond to sRNAs. We conclude that the model strain HG003, a NCTC8325 derivative commonly used for S. aureus genetic regulation studies, has only about 50 bona fide sRNAs, indicating that these RNAs are less numerous than commonly stated. Among them, about half are associated to the S. aureus sp. core genome and a quarter are possibly expressed in other Staphylococci. We hypothesize on their features and regulation using bioinformatic approaches.

Project description:An unbiased approach to defining bona fide tumor neoepitopes that mediate cancer immunity

Project description:Staphylococcus aureus strain:HG003 Genome sequencing

Project description:The post-translational modification of proteins by ubiquitination is a highly regulated process that involves a dynamic, three-step enzymatic cascade, where more than 600 E3 ligases play a critical role in recognizing specific substrates for modification. Separating bona fide targets of E3s from E3-interacting proteins remains a major challenge in the field. In this study, we present BioE3, a novel approach for identifying substrates of ubiquitin-like (UbL) E3 ligases of interest. Using BirA-E3 ligase fusion proteins and bioUbLs, the method facilitates site-specific biotinylation of UbL-modified substrates for proteomic identification. We demonstrate that the BioE3 system can identify both known and novel targets of two RING-type ubiquitin E3 ligases: RNF4, known to be involved in DNA damage response and the regulation of PML nuclear bodies, and MIB1, implicated in endocytosis, autophagy, and centrosomal protein homeostasis. We further show the versatility of BioE3 by identifying targets of an organelle-specific E3 (MARCH5) and a relatively uncharacterized E3 (RNF214). Furthermore, we show that BioE3 works with HECT-type E3 ligases and identify novel targets of NEDD4 involved in vesicular trafficking. BioE3 is a powerful tool that enables identification of bona fide substrates of UbL E3 ligases and how they change with chemical perturbations, which may be useful for the emerging applications in targeted protein degradation (TPD). BioE3 may also be applicable for UbLs beyond Ub and SUMO, as well as other E3 ligase classes. The resulting knowledge can shed light on the regulation of cellular processes by the complex UbL network, advancing our understanding of fundamental biological mechanisms.

Project description:Microglia provide a front-line defense against neuroinvasive viral infection, however, determination of their bona fide transcriptional profiles under conditions of health and disease is challenging. Here, we used a combination of experimental tools to delineate the overall transcriptional landscape of microglia during viral infection. By exploiting the ribosomal tagging approach, we developed the concept of enrichment of relevant marker genes by comparing immunoprecipitated RNA with total RNA. Enriched transcripts corresponding to genes expressed in target cells were instrumental in defining bona fide signatures of microglia. With this approach, we generated a comprehensive and accurate transcriptome of microglia at the in situ environment under conditions of health and virus infection. These unified microglial signatures may serve as a benchmark to retrospectively assess ex vivo artefacts from available atlases. Leveraging the microglial translatome, we found enrichment of genes implicated in T-cell activation and cytokine production during the course of VSV infection. These data linked microglia with T-cell re-stimulation and further underscored that microglia shape anti-viral T-cell responses in the brain. Collectively, this study faithfully defines the transcriptional landscape of microglia in steady state and during viral encephalitis and highlights cellular interactions between microglia and T cells that contribute to the control of virus dissemination.

Project description:Staphylococcus aureus strain:HG003 Genome sequencing and assembly

Project description:Staphylococcus aureus strain:HG003 Transcriptome or Gene expression

Project description:Dynamic interactions between RNA and RNA-binding proteins (RBPs) regulate a broad spectrum of bacterial functions. Here, we have characterised how the RBPome is dynamically rewired during the E. coli life cycle. We applied Orthogonal Organic Phase Separation (OOPS) coupled with an RNase digestion step to shortlist bona fide bacterial RBPs and assessed whether proteins bound RNA differentially express at different cell proliferation stages.