Project description:Glioblastomas type A cell line (U-2987) was transfected with pLEX-blast-V5-YFP (control), and pLEX-blast-V5-SFRP2 (SFRP2), and type B cell culture (U-2982, U-343 MG) were transfected with pLEX-blast-V5-YFP (control), and pLEX-blast-V5-SOX2 (SOX2). Then RNA-seq was performed and used to analyse their regulation in the gene expression level.

Project description:Myelofibrosis is a severe myeloproliferative neoplasm characterised by increased numbers of abnormal bone marrow megakaryocytes that induce progressive fibrosis, destroying the hematopoietic microenvironment. To determine the cellular and molecular basis for aberrant megakaryopoiesis in myelofibrosis, we performed high-throughput single-cell transcriptome profiling of 50,702 hematopoietic stem/progenitor cells (HSPCs), and single-cell proteomics, genomics and functional assays. We identified an aberrant pathway for direct megakaryocyte differentiation from the earliest stages of hematopoiesis in myelofibrosis and associated aberrant molecular signatures, including surface antigens selectively expressed by JAK2-mutant HSPCs. Myelofibrosis megakaryocyte progenitors were heterogeneous, with distinct expression of fibrosis and proliferation-associated genes and putative therapy targets. We validated the integrin G6B as a promising JAK2-mutant clone-specific surface antigen, warranting further development as an immunotherapeutic target. Our study paves the way for selective immunotherapeutic targeting in myelofibrosis and more broadly illustrates the power of single-cell multi-omics to discover tumor-specific therapeutic targets and mediators of tissue fibrosis.

Project description:mRNA-based immunotherapeutics have garnered widespread interest for their potential to revolutionize cancer treatment. In this study, we have established a personalized and customizable mRNA-therapeutic approach that effectively targets a plurality of tumor antigens and demonstrated potent anti-tumor response in preclinical brain tumor models. Our platform uniquely addresses the challenge of tumor heterogeneity and low antigen burden, two key deficiencies in targeting classically immunotherapy-resistant CNS malignancies.

Project description:mRNA-based immunotherapeutics have garnered widespread interest for their potential to revolutionize cancer treatment. In this study, we have established a personalized and customizable mRNA-therapeutic approach that effectively targets a plurality of tumor antigens and demonstrated potent anti-tumor response in preclinical brain tumor models. Our platform uniquely addresses the challenge of tumor heterogeneity and low antigen burden, two key deficiencies in targeting classically immunotherapy-resistant CNS malignancies.

Project description:mRNA-based immunotherapeutics have garnered widespread interest for their potential to revolutionize cancer treatment. In this study, we have established a personalized and customizable mRNA-therapeutic approach that effectively targets a plurality of tumor antigens and demonstrated potent anti-tumor response in preclinical brain tumor models. Our platform uniquely addresses the challenge of tumor heterogeneity and low antigen burden, two key deficiencies in targeting classically immunotherapy-resistant CNS malignancies.

Project description:mRNA-based immunotherapeutics have garnered widespread interest for their potential to revolutionize cancer treatment. In this study, we have established a personalized and customizable mRNA-therapeutic approach that effectively targets a plurality of tumor antigens and demonstrated potent anti-tumor response in preclinical brain tumor models. Our platform uniquely addresses the challenge of tumor heterogeneity and low antigen burden, two key deficiencies in targeting classically immunotherapy-resistant CNS malignancies.

Project description:Cancer immunotherapies have produced remarkable results in B-cell malignancies; however, optimal cell surface targets for many solid cancers remain elusive. Here, we present an integrative proteomic, transcriptomic, and epigenomic analysis of tumor specimens along with normal tissues to identify biologically relevant cell surface proteins that can serve as immunotherapeutic targets for neuroblastoma, the often fatal childhood cancer of the developing nervous system. We apply this approach to human-derived cell lines (N=9) and cell/patient-derived xenograft (N=12) models of neuroblastoma. Plasma membrane-enriched mass spectrometry identified 1,461 cell surface proteins in cell lines and 1,401 in xenograft models, respectively. Additional proteogenomic analyses revealed 71 high-confidence candidate immunotherapeutic targets and we prioritized Delta-like canonical notch ligand 1 (DLK1) for further study. High expression of DLK1 directly correlated with the presence of a super-enhancer spanning the DLK1 locus. Robust cell surface expression of DLK1 was validated by immunofluorescence, flow cytometry, and immunohistochemistry. Short hairpin RNA mediated silencing of DLK1 in neuroblastoma cells resulted in increased cellular differentiation. ADCT-701, a DLK1-targeting antibody-drug conjugate (ADC), showed potent and specific cytotoxicity in DLK1-expressing neuroblastoma xenograft models. Finally, we also found that DLK1 is highly expressed in several adult cancer types including adrenocortical carcinoma (ACC), pheochromocytoma/paraganglioma (PCPG) and small cell lung cancer (SCLC) suggesting potential clinical benefit beyond neuroblastoma. A clinical trial has been developed for evaluating ADCT-701 in neuroendocrine tumors in adults (https://www.clinicaltrials.gov/study/NCT06041516?term=adct-701&rank=1). Therefore, comprehensive characterization of cancer surfaceomes can provide biologically relevant immunotherapy targeting strategies.

Project description:To elucidate molecular features of the cells of Hippocampus, their progeny at each differentiation stage, and surrounding cells in hippocampus under blast wave-induced changes, cells were profiled from matched hippocampus of 3 mice that had received blast injury and 3 controls.Cell type specific gene expression responding to (blast-related traumatic brain injury, bTBI) were revealed, some of which were closely associated with pathogenesis post-injury. Furthermore, the diverse cell to cell interaction networks uncovered an array of cellular processes under bTBI. Our gene expression atlas provides extensive resources for future researches regarding bTBI induced pathogenesis, its therapeutic interventions or diagnostic tests.

Project description:Malignant peripheral nerve sheath tumor (MPNST) is a rare sarcoma that lacks effective therapeutic strategies. By characterizing recurrent gene copy number aberrations, we gain insight into the most altered pathways with the purpose of scanning possible therapeutic targets. We conducted a microarray-based comparative genomic hybridization profiling of two cohorts of primary MPNST tissue samples including 25 patients treated at The University of Texas MD Anderson Cancer Center and 26 patients from Tianjin Cancer Hospital. All samples had at least 90% tumor content. Commercially available normal genomic DNAs were used as control.

Project description:The differentiation of stem-like cells of tumors may contribute to the cellular heterogeneity of breast cancers. We report the propagation of highly enriched mouse mammary cancer stem cells that retain the potential to differentiate both in vivo and in culture and their use to identify chemical compounds that influence both self-renewal and differentiation. We identify epithelial tumor initiating cells (ETIC) that expresses lineage markers of both basal and luminal mammary cell lineages and retains the potential to generate heterogeneous tumors similar to the tumor of origin from even single cells. ETIC can progress through a Rho associated coil-coil protein kinase 1 (ROCK1) dependent, epithelial to mesenchymal transition to generate a second cell type capable of initiating tumors of limited heterogeneity. The propagation of ETIC will increase the opportunities for identifying new therapeutic compounds that may inhibit or prevent progression of some types of breast cancer. These data compare the gene expression pattern of ETIC and MTIC. Total RNA obtained from ETIC and MTIC cells, allowing the comparison of gene expression patterns and the selection of potential targets.