Project description:Area under the curve label free quantitative proteomics on membrane enriched sampels from tumors +/- AP2 complex.

Project description:Quantitative label free proteomics of BioID enriched proteins

Project description:Ewing Sarcoma (EwS) is a rare pediatric malignancy characterized by a unique t(11:22) (q24;q12) translocation resulting in the EWSR1::FLI1 fusion. Recent reports indicate the EWSR1::FLI1 fusion onco-protein drives aberrant expression of numerous transcripts, including Lipoxygenase Homology Domains 1 (LOX¬HD1). Given its highly restricted protein expression pattern and role in EwS tumorigenesis and metastasis, LOXHD1 may serve as a novel immunotherapeutic target in this malignancy. LOXHD1 immunogenic epitopes restricted to HLA-A*02:01 allowed for the isolation of high avidity TCRs. LOXHD1-specific TCR engineered CD8+ T cells confer cytotoxic activity against a panel of HLA-A*02:01+ EwS tumor cell lines and adoptive transfer leads to tumor eradication in a mouse xenograft model of EwS. This study nominates LOXHD1 as an onco-fusion regulated / non-mutated EwS tumor associated antigen with expression limited to inner hair cells of the cochlea, adult testis, and EwS

Project description:Label free quantitative LC-MS/MS anaysis of BioID enriched proteins.

Project description:BioID2 Zebrafish Interaction Proteomics analyzed by nanoscale capillary LC coupled to a Fusion Lumos OT with label-free quantitation.

Project description:Quantitative label free proteomic characterization of liver secretomes in mice fed either ona regular or calorie restricted diet.

Project description:Antimicrobial-induced DNA damage, and subsequent repair via upregulation of DNA repair factors, including error-prone translesion polymerases, can lead to the increased accumulation of mutations in the microbial genome, and ultimately increased risk of acquired mutations associated with antimicrobial resistance. While this phenotype is well described in bacterial species, it is less thoroughly investigated amongst microbial fungi. Here, we monitor DNA damage induced by antifungal agents in the fungal pathogen Candida albicans, and find that commonly used antifungal drugs are able to induce DNA damage, leading to the upregulation of transcripts encoding predicted error-prone polymerases and related factors. We focus on REV1, encoding a putative error-prone polymerase, and find that while deleting this gene in C. albicans leads to increased sensitivity to DNA damage, it also unexpectedly renders cells more likely to incur mutations and evolve resistance to antifungal agents. We further find that deletion of REV1 leads to a significant depletion in the uncharacterized protein Shm1, which itself plays a role in fungal mutagenesis. Together, this work lends new insight into previously uncharacterized factors with important roles in the DNA damage response, mutagenesis, and the evolution of antifungal drug resistance.

Project description:The analysis to investigate the change in proteome of USP8-depleted cells

Project description:Differential protein interaction analysis following IP, LC-MS/MS, and label-free quantitation on an Orbitrap Astral

Project description:To gain a comprehensive molecular and functional view of the tumors in their microenvironment, we performed a deep mass spectrometry-based proteomic analysis of 168 tumors from 72 patients from primary, relapsed, and metastatic tumors. Analysis of more than 10,000 proteins across patients revealed novel insights into cancer prognosis, chemo-resistance, and progression. We found ferroptosis inhibition as a potential mediator of EWS chemo-resistance and identified novel subclasses of EWS that link the tumor immune landscape with DNA damage repair, ubiquitin-related proteins, and patient prognosis. Validation by multiplexed immunofluorescence imaging confirmed a significant association between patient prognosis and tumor neutrophils, suggesting potential neutrophil-targeted strategies for future treatment