Project description:Treatment of Mycobacterium tuberculosis infections is a challenging task due to a growing number of resistant clinical isolates as well as an almost empty drug development pipeline. To identify new antibiotic hits, we screened a focused library of 400 synthetic compounds derived from a recently discovered molecule with promising anti-mycobacterial activity. A suite of more potent hit molecules was deciphered with sub-micromolar activity. Utilising tailored affinity-based probes for chemical proteomic investigations, we successfully pinpointed the mycolic acid transporter MmpL3 and two epoxide hydrolases, EphD and EphF, also linked to mycolic acid biosynthesis, as specific targets of the compounds. These targets were thoroughly and independently validated by activity assays, under- and overexpression, resistance generation, and proteomic studies. Structural refinement of the most potent hit molecules led to the development of a new lead compound that demonstrates enhanced biological activity in M. tuberculosis, low human cytotoxicity, and improved solubility and oral bioavailability − traits that are often challenging to achieve with anti-mycobacterial drugs. Overall, drug-likeness, as well as the dual mode of action, addressing the mycolic acid cell wall assembly at two distinct steps, holds significant potential for further in vivo applications.

Project description:Part of manuscript for the identifiaction of the cellular targets of Chlorotonil and its derivatives,

Project description:In this manuscript we describe our work on the development of a label-free chemoproteomics screening platform for cysteine reactive covalent fragments on a 96 well plate format. Within this workflow, we profile cysteine reactive fragments by competition with the hyper-reactive iodoacetamide desthiobiotin (IA-DTB) in cell lysates and live cells. We employ label free quantification and data independent acquisition (DIA) on an Evosep One – Bruker timsTOF Pro. The platform was used to screen a library of 80 Cys-reactive covalent fragments in HEK293T and Jurkat cell lysate, identifying functionally relevant hit fragments for numerous cysteine sites and demonstrating the utility of the approach in expanding the ligandable proteome. We have also validated a number of selective interactions through dose response and further expanded our proteomics platform to perform hit expansion studies and in-cell validation.

Project description:In this manuscript we describe our work on the development of a label-free chemoproteomics screening platform for cysteine reactive covalent fragments on a 96 well plate format. Within this workflow, we profile cysteine reactive fragments by competition with the hyper-reactive iodoacetamide desthiobiotin (IA-DTB) in cell lysates and live cells. We employ label free quantification and data independent acquisition (DIA) on an Evosep One – Bruker timsTOF Pro. The platform was used to screen a library of 80 Cys-reactive covalent fragments in HEK293T and Jurkat cell lysate, identifying functionally relevant hit fragments for numerous cysteine sites and demonstrating the utility of the approach in expanding the ligandable proteome. We have also validated a number of selective interactions through dose response and further expanded our proteomics platform to perform hit expansion studies and in-cell validation.

Project description:The field of graft preservation has made considerable strides in recent years improving outcomes related to solid organ restoration and regeneration. In lungs, the use of ex vivo lung perfusion (EVLP) in line with devices and treatments has shown promising results within preclinical and clinical studies with the potential to improve graft quality. The benefit of the therapy would be to render marginal and declined donor lungs suitable for transplantation, ultimately increasing the donor pool available for transplantation. Additionally, such therapies used in machine perfusion could also increase preservation time, facilitating logistical planning. Cytokine adsorption has been demonstrated as a potentially safe and effective therapy when applied to the EVLP circuit and post transplantation. The mechanism by which this treatment improves the donor lung on a molecular basis is not yet fully elucidated. We hypothesized that there were characteristic inflammatory and immunomodulatory differences between lungs treated with and without cytokine adsorption, reflecting in proteomic changes in gene ontology pathways and across inflammation-related proteins. In the current study we investigate the molecular mechanisms and signaling pathways of how cytokine adsorption impacts the lung function when used during EVLP and when used post transplantation as hemoperfusion in a porcine model. Lung tissue from EVLP and post lung transplantation were analyzed for their proteomic profile using mass spectrometry. The inflammatory and immune processes were compared between the treated and the non-treated groups to show the differences occurring between the forms of graft preservation.

Project description:N6-methyladenosine (m6A) is the most prevalent mRNA modification with diverse regulatory roles in mammalian cells. While its functions are well-documented in mouse embryonic stem cells (mESCs), its role in human pluripotent stem cells (hPSCs) remains to be fully explored. METTL3 is the main enzyme responsible for m6A deposition. Here, using a METTL3 inducible knockout (iKO) system, we uncovered that, unlike in mESCs, METTL3 was indispensable for hPSC maintenance. Importantly, loss of METTL3 caused significant upregulation of pluripotency factors including naïve pluripotency genes and failure to exit pluripotency, thus impaired stem cell differentiation towards embryonic and extraembryonic cells including trophoblasts. Mechanistically, METTL3 iKO in hPSCs substantially increased expression and enhancer activities of two primate-specific transposable elements (TEs), SVA_D and HERVK/LTR5_Hs, which are normally modified by METTL3-dependent m6A. METTL3 loss activated SVA_D by lowering H3K9me3 deposition, and increased chromatin accessibility at LTR5_Hs through the naïve and other pluripotency factors. Conversely, we discovered that the activated SVA_D and LTR5_Hs loci positively regulated naïve gene expression by directly interacted with their promoters. These findings thus reveal that METTL3-dependent m6A RNA methylation has critical roles in suppressing TE expression and in the human pluripotency regulatory network.

Project description:In this manuscript we describe our work on the development of a label-free chemoproteomics screening platform for cysteine reactive covalent fragments on a 96 well plate format. This platform profiles cysteine reactive fragments by competition with the hyper-reactive iodoacetamide desthiobiotin (IA-DTB) in cell lysates and live cells. We employ label free quantification and data independent acquisition (DIA) on an Evosep One – Bruker timsTOF Pro. In this submission we report this use of global proteomics to explore protein expression in HEK293T.

Project description:Prediction of proteins and associated biological pathways from lipid analyses via MALDI MSI is a pressing chal-lenge. We introduced "dry proteomics," using MALDI MSI to validate spatial localization of identified optimal clusters in lipid or protein imaging. Consistent cluster appearance across omics images suggests association with specific lipid and protein pathways, forming the basis of dry proteomics. The methodology was refined using rat brain tissue as a model, then applied to human glioblastoma, a highly heterogeneous cancer. Sequen-tial tissue sections underwent omics MALDI MSI and unsupervised clustering. Differentiated lipid and protein clusters, with distinct spatial locations, were identified. Spatial omics analysis facilitated lipid and protein charac-terization, leading to a predictive model identifying clusters in any tissue based on unique lipid signatures and predicting associated protein pathways. Application to rat brain slices revealed diverse tissue subpopulations, including successfully predicted cerebellum areas. Similar analysis on 50 glioblastoma patients confirmed lipid-protein associations, correlating with patient prognosis.

Project description:Understanding how genetic variation translates into complex phenotypes remains a fundamental challenge. Here, we address this by mapping genome-to-proteome relationships in 800 progeny of a cross between two yeast strains adapted to distinct environments. Despite the modest genetic distance between the parents, we observed remarkable proteomic diversity and mapped over 6,400 genotype-protein associations, with more than 1,600 linked to individual genetic variants. Proteomic adaptation emerged from a conserved network of cis- and trans-regulatory variants, often originating from proteins not traditionally linked to gene regulation. This atlas allowed us to forecast organismal fitness effects across diverse conditions. By connecting genomic and proteomic landscapes at unprecedented resolution, our study provides a framework for predicting the phenotypic outcomes of natural genetic variation.

Project description:The intricate aetiology of type 1 diabetes mellitus (T1DM) implicating a detrimental cross talk between immune cells and insulin producing b-cells leading to their destruction has stumped the development of effective disease modifying therapies. The discovery that the pharmacological activation of LRH-1/NR5A2 can revert hyperglycemia in pre-clinical mouse models of T1DM by attenuating the autoimmune attack coupled to b-cell survival/regeneration, prompt us to investigate whether LRH-1/NR5A2-mediated immune tolerization could be achieved in individuals with T1DM and improve islet survival and function subsequent to xenotransplantation. We found that LRH-1/NR5A2 activation using the agonist BL001 blunted the pro-inflammatory genetic signature and cytokine secretome of both monocyte-derived macrophages (MDM1) and mature dendritic cells (mDCs) from individuals with T1DM. Mechanistically, mitohormesis was induced in MDM1 restricting pro-inflammation propagation while mitochondria turnover was increased in mDCs assisting transit towards a tolerogenic phenotype. BL001 treatment also increased T-regulatory cells within the T-cell subpopulation. BL001-treated MDM1, mDCs or T-cells impeded T-effector cell expansion. Engraftment and function of human islets transplanted into hyperglycemic immunocompetent mice was enhanced by BL001 treatment leading to improved glycemia. Collectively, LRH-1/NR5A2 agonism fosters a coordinated re-programming of T1DM immune cells from a pro- to an anti-inflammatory/tolerizing phenotype empowering them to repress cytotoxic T-cell proliferation and facilitates islet engraftment and function after transplantation. Our finding demonstrate the feasibility of re-establishing human immune tolerance within a pro-inflammatory environment, rather than suppression, opening an unprecedent pharmacological therapeutic venue for T1DM