Project description:Backgroung: Antibody and cell-based immunotherapies, e.g., antibody-drug-conjugates and CAR-T cells, targeted at cell-surface proteins, currently revolutionize clinical oncology. However, target selection warrants a better understanding of the surface-endocytome and how it is modulated by the tumor microenvironment. Here, we unravel the surface-endocytome landscape and its remodeling by hypoxia in primary cultures from glioblastoma (GBM) patients that currently lack targeted therapies. Methods. We employed a comprehensive approach for global and dynamic mapping of surfaceome and endocytosed (endocytome) proteins in primary GBM cultures at normoxia or hypoxia. Selected target candidates were validated by immunofluorescence analyses in patient tumor sections, spheroids, and 2D cultures, and were finally confronted by ADC cytotoxicity studies. Results: We reveal a heterogeneous surface-endocytome profile across GBM cultures from three patients representing different transcriptional subtypes. CD44 emerged as a commonly abundant surfaceome antigen across GBM cultures, and we established a direct correlation between CD44 endocytic activity and ADC cytotoxicity. We elucidate how hypoxia profoundly reshapes the global surface-endocytome, and identify several hypoxia-induced antigens (CXADR, CD47, BSG, CD81, FXYD6), unique to or shared among GBM cultures. Importantly, we highlight the limited correlation between transcriptomics and proteomics, emphasizing the critical role of membrane protein enrichment strategies and targeted mass spectometry. Conclusions: These studies provide a comperehensive map of the surface-endocytome and its remodeling by hypoxia in GBM as a resource for target discovery. As proof-of-concept, we validate several proteins, either abundantly expressed in normoxia or induced by hypoxia, for further exploration as potential targets of immunotherapeutic approaches in GBM.

Project description:Background: Antibody and cell-based immunotherapies, e.g., antibody-drug-conjugates and CAR-T cells, targeted at cell-surface proteins, currently revolutionize clinical oncology. However, target selection warrants a better understanding of the surface-endocytome and how it is modulated by the tumor microenvironment. Here, we unravel the surface-endocytome landscape and its remodeling by hypoxia in primary cultures from glioblastoma (GBM) patients that currently lack targeted therapies. Methods. We employed a comprehensive approach for global and dynamic mapping of surfaceome and endocytosed (endocytome) proteins in primary GBM cultures at normoxia or hypoxia. Selected target candidates were validated by immunofluorescence analyses in patient tumor sections, spheroids, and 2D cultures, and were finally confronted by ADC cytotoxicity studies. Results: We reveal a heterogeneous surface-endocytome profile across GBM cultures from three patients representing different transcriptional subtypes. CD44 emerged as a commonly abundant surfaceome antigen across GBM cultures, and we established a direct correlation between CD44 endocytic activity and ADC cytotoxicity. We elucidate how hypoxia profoundly reshapes the global surface-endocytome, and identify several hypoxia-induced antigens (CXADR, CD47, BSG, CD81, FXYD6), unique to or shared among GBM cultures. Importantly, we highlight the limited correlation between transcriptomics and proteomics, emphasizing the critical role of membrane protein enrichment strategies and targeted mass spectrometry. Conclusions: These studies provide a comprehensive map of the surface-endocytome and its remodeling by hypoxia in GBM as a resource for target discovery. As a proof-of-concept, we validate several proteins, either abundantly expressed in normoxia or induced by hypoxia, for further exploration as potential targets of immunotherapeutic approaches in GBM.

Project description:Glioblastoma (GBM) is the most common and devastating malignant brain tumor in adults. The mortality rate is very high despite different treatments. New therapeutic targets are therefore highly needed to improve patient care. Cell-surface proteins represent attractive targets due to their accessibility, their involvement in essential signaling pathways, and their dysregulated expression in cancer. Moreover, they are potential targets for CA-based immunotherapy or mRNA vaccine strategies. However, cell-surface proteins are often underrepresented in standard proteomic data sets, due to their poor solubility and lower expression levels compared to intracellular proteins. In this context, we investigated GBM-associated surfaceome by comparison to healthy astrocytes surfaceome to identify new specific targets to GBM. For this purpose, biotinylation of cell surface proteins has been carried out in GBM and healthy astrocytes cell lines. Biotinylated proteins were purified on streptavidin beads and analyzed by shotgun proteomics. After filtering our data with Cell Surface Proteins Atlas (CSPA) and Gene Ontology, 78 overexpressed or exclusive in GBM have been identified. Validation has been performed using Human Protein Atlas. In this context, we identified 21 specific potential targets for GBM including 5 mutated proteins (RELL1, CYBA, EGFR, and MHC I proteins). Taken together, we identified potential targets for immune therapy strategies in GBM.

Project description:Transcriptional profiling of human mesenchymal stem cells comparing normoxic MSCs cells with hypoxic MSCs cells. Hypoxia may inhibit senescence of MSCs during expansion. Goal was to determine the effects of hypoxia on global MSCs gene expression. Two-condition experiment, Normoxic MSCs vs. Hypoxic MSCs.

Project description:We performed this microRNA analysis on GBM cells and found that numerous miRNAs were differentially expressed under hypoxia condition. And we noticed that the tumor cells are able to survive in hypoxia and low nutrient microenvironment, resist external pressure and then exhibit invasion and metastasis, and also, reduce the sensitivity to chemotherapy, radiotherapy and immunotherapy. We wanted to screen numerous significantly expressed microRNAs which could mediate the biological process under hypoxia.

Project description:Glioblastoma (GBM) is the most common and aggressive primary brain tumor in adults, with glioma initiating cells (GICs) implicated to be critical for tumor progression and resistance to therapy. The hypoxic tumor microenvironment has been shown to play an important role to maintain the GICs; however, the mechanisms regulating responses of GICs to hypoxia remain poorly understood. We used microarray to to detail the global change of gene expression in GICs cultured under hypoxia compared to normoxia and identified de-regulated genes during hypoxia. CD133+ D456MG GICs were cultured under 1% O2 or 20% O2 for 12 hours. Then RNA was extracted and gene expression was profiled by microarray.

Project description:How cancer cells adapt to hypoxia during tumor development remains an important question. The hypothesis tested in the present study was that tumor cell-derived exosome vesicles (also known as microvesicles or extracellular vesicles) are mediators of hypoxia-dependent intercellular signaling in glioblastoma (GBM), i.e. highly aggressive brain tumors characterized by hypoxia and a vascular density that is among the highest of all human malignancies. In vitro hypoxia experiments and studies with patient materials reveal the enrichment in exosomes of hypoxia-regulated mRNAs and proteins, several of which were associated with poor patient prognosis. We show that cancer cell exosomes mediate hypoxia-dependent, phenotypic modulation of stromal cells in vitro and ex vivo, resulting in accelerated GBM tumor angiogenesis and growth in mice. These data suggest that exosomes constitute potent mediators of hypoxia-driven tumor development, and circulating multiparameter biomarkers of tumor hypoxia. U87 MG glioblastoma cells were grown at normoxic (21% oxygen) or hypoxic (1% oxygen) conditions for 48 hours. Conditioned media from normoxic and hypoxic cells were then used to isolate exosomes by differential centrifugation. Both cells and exosomes were lysed in Trizol reagent, and RNA was isolated.Total RNA from all samples (four types of samples in three biological repilicates) was subjected to genome-wide transcriptional analysis with Illumina HumanHT-12 V3.0 expression beadchip. Gene expression profile obtained from hypoxic U87 MG glioblastoma cells was compared to the profile of normoxic control cells. Analogically, gene expression profile obtained from hypoxic U87 MG cells was compared to the profile of exosomes secreted by normoxic U87 MG cells.

Project description:Detailed knowledge of cell surface proteins for isolating well-defined populations of human pluripotent stem cells (hPSCs) would significantly enhance their characterization and translational potential. Normal H9 human embryonic stem cells and the KB3 human induced pluripotent stem cell lines were analyzed by Cell Surface Capture Technology, and in parallel transcript profiles from five independent samples (i.e., Replicas 1-5 for each) were performed to facilitate protein and transcriptomic comparisons. The study compared gene expression profiles of pluripotent stem cells with Cell Surface Capture technology generated N-glycoprotein surfaceome analyses of the same cell types.

Project description:So far, there is no known regulatory circuits that mediate filamentation of the pathogenic yeast Candida albicans exclusively in response to hypoxia. In this study, we performed a quantitative analysis of gene deletion mutants from different collections of protein kinases and transcriptional regulators to identify specific regulator of the hypoxic filamentation. Our work uncovered two transcription factors, Ahr1 and Tye7, that act as prominent regulators of C. albicans filamentation specifically under hypoxia. In summary, we used genome-wide transcriptional profiling and promoter occupancy to characterize both Ahr1 and Tye7 regulons associated with the hypoxic filamentation in C. albicans.

Project description:Surface proteins are of fundamental importance for formation of synaptic connections and activity-dependent plasticity. Here, we used a spatiotemporally resolved cell-surface proteotype analysis to characterize the neuronal surface-exposed proteome, or surfaceome, during neuronal development and synapse formation in primary neuronal cultures. We established a map of the neuronal surfaceome, which includes about 1,000 surface proteins, and analyzed the dynamic remodeling of the quantitative surfaceome during development. We identified time-resolved surface-abundance profile clusters that correspond to distinct stages of neuronal development. We discovered that surface abundance changes can correlate with or be uncoupled from the total cellular abundance. Finally, we observed system-wide surfaceome modulation in response to homeostatic synaptic scaling and exocytosis of diverse cargo during long-term potentiation.