Project description:The classical sacrococcygeal chordoma tumor presents with a typical morphology of lobulated myxoid tumor tissue with cords, strands and nests of tumor cells consisting of small non-vacuolated cells, intermediate cells with a wide range of vacuolization and large heavily vacuolated (physaliferous) cells. Because of its rare incidence, lack of suited model systems and technical limitations analysis was only performed on bulk tumor mass neglecting its heterogeneous composition. We aimed at elucidating the differences between small non-vacuolated and large physaliferous cells on the genomic and transcriptomic level. Secondly, we intended to clarify whether the observed cell types are derived from genetically distinct clones or rather represent different phenotypes. Using the chordoma cell line MUG-Chor1 we monitored morphological changes via time lapse experiments. We isolated pure fractions of each phenotype by means of laser microdissection or micromanipulation allowing phenotype-specific analysis. Pools of 100 cells each were genetically profiled after whole genome amplification by array comparative genomic hybridization. For expression analysis 20 cells each were subjected to whole transcriptom amplification, forwarded to RNA microarray analysis and qRT-PCR. Time lapse analysis unveiled small non-vacuolated cells to develop into large physaliferous cells via intermediate cells containing an increasing amount of vacuoles. Furthermore, we showed small and large physaliferous cells to proliferate at the same rate but intermediate cells to be the most proliferating cell phenotype. Small non-vacuolated and large physaliferous cells showed identical copy number variations. Despite their obvious morphological disparities we detected only modest changes in over all gene expression. However, verification of candidate genes yielded significant up-regulation of ALG11 (700-fold), PPP2CB (18.6-fold), and UCHL3 (18.7-fold) in large physaliferous cells. Of two different cell types (large and small MUG-Chor1 cells) we analysed each in triplicates. In total 6 cell pools were analysed.

Project description:ChIP sequencing of chordoma UCH-1 cell line. A well characterised chordoma cell line which bears all the morphological and immunohistochemical features of a chordoma (large vacuolated slow-growing cells, brachyury and cytokeratin-positive) have been used in this study. Chromatin immunoprecipitation using a well characterised anti-Brachyury antibody which has been used in immunohistochemistry of chordoma samples and previous ChIP studies in other systems. This data is part of a pre-publication release. For information on the proper use of pre-publication data shared by the Wellcome Trust Sanger Institute (including details of any publication moratoria), please see http://www.sanger.ac.uk/datasharing/

Project description:To understand the mechanism of disease progression in psoriasis, we defined Asian small plaque psoriasis (small psoriasis) and Asian intermediate plaque psoriasis (intermediate psoriasis) as psoriasis subtypes with limited disease progression, and compared their cellular and molecular signatures with the classic subtype of Western large plaque psoriasis (large psoriasis; GSE30999). Transcriptome analyses in pre-treatment skin biopsies from patients with Asian small and intermediate plaque psoriasis. 12 Asian small plaque psoriasis skin biopsy tissues (7 lesional and 5 non-lesional skin) and 15 Asian intermediate plaque psoriasis skin biopsy tissues (7 lesional and 8 non-lesional skin). GCRMA (using gcrma package from R/Bioconductor) and adjusted for batch effect. The expression data was combined with Western large psoriasis (GSE30999). Using a normalization based upon quantiles, the expression data was normalized based upon a specified normalization distribution of GSE30999 (see publication for GSE67853). The complete dataset representing: (1) 12 Asian small plaque psoriasis Samples, (2) 15 Asian intermediate plaque psoriasis Samples, and (3) 130 Western large plaque psoriasis Samples from GSE30999 (re-processed), is linked below as a supplementary file.

Project description:Interactions between Macrophages and T-lymphocytes: Tumor Sneaking Through Intrinsic to Helper T cell Dynamics ROB J. DE BOER AND PAULINE HOGEWEG Bioinformatics Group, University of Utrecht, Padualaan 8, 3584 CH Utrecht, The Netherlands Abstract In a mathematical model of the cellular immune response we investigate immune reactions to tumors that are introduced in various doses. The model represents macrophage T-lymphocyte interactions that generate cytotoxic macrophages and cytotoxic T-lymphocytes. In this model antigens (tumors) can induce infinitely large T-lymphocyte effector populations because (a) effector T-lymphocytes are capable of repeated proliferation and (b) we have omitted immunosuppression. In this (proliferative) model small doses of weakly antigenic tumors grow infinitely large (i.e. sneak through) eliciting an immune response of limited magnitude. Intermediate doses of the same tumor induce larger immune responses and are hence rejected. Large doses of the tumor break through, but their progressive growth is accompanied by a strong immune response involving extensive lymphocyte proliferation. Similarly a more antigenic tumor is rejected in intermediate doses and breaks through in large doses. Initially small doses however lead to tumor dormancy. Thus although the model is devoid of explicit regulatory mechanisms that limit the magnitude of its response (immunosuppression is such a mechanism), the immune response to large increasing tumors may either be (a) a stable reaction of limited magnitude (experimentally known as tolerance or unresponsiveness) or (b) a strong and ever increasing reaction. Unresponsiveness can evolve because in this model net T-lymphocyte proliferation requires the presence of a minimum number of helper T cells (i.e. a proliferation threshold). Unresponsiveness is caused by depletion of helper T cell precursors.

Project description:IFN-g-induced gene expression profiles of UM-Chor1 cells were assessed by microarray analysis Chordoma is a rare bone tumor derived from notochord, which has shown to be resistant to conventional therapy, including chemotherapy and radiotherapy. Immunotherapy has the potential to be effective in cancers with resistance to conventional therapy. Checkpoint inhibition, including Programmed cell Death 1 (PD-1)/Programmed cell Death protein 1 (PD-L1) blockade has shown great promise in treating diverse cancers. The purpose of this study was to investigate the potential of anti-PD-L1 antibody therapy for chordoma. To this end, using 4 chordoma cell lines, we examined the expression of PD-L1 and performed in vitro NK cells killing assay for antibody-dependent cell-mediated cytotoxicity (ADCC) activity mediated by the anti-PD-L1 antibody, avelumab. Here, the expression of PD-L1 was markedly upregulated by IFN-g in all 4 chordoma cell lines, which resulted in increasing the sensitivity to ADCC. Next, to model a patient that received a tumor-antigen specific vaccine, chordoma cells were co-incubated with brachyury specific CD8+ T cells, culminating in significant upregulation of PD-L1 on the tumor cells mediated by CD8+ T cells IFN-g production. The functional consequence was the sensitivity of chordoma cells to ADCC mediated by avelumab. Finally, residential cancer stem cell subpopulations of chordoma cells were killed by avelumab-mediated ADCC to the same degree as non-cancer stem cell populations. Our findings show the potential of avelumab therapy in chordoma; a) alone, to enable endogenous NK cells to kill chordoma cells via ADCC, or b) in conjunction with T cells immunotherapy such a vaccine, to exploit enhanced NK cell killing of chordoma cells via ADCC.

Project description:The prognostic factors of skull base chordoma associated with outcomes of patients after surgical resection remain poorly defined. This project aimed to identify a novel prognostic factor for patients with skull base chordoma. Using a proteomics approach, we screened tumor biomarkersthat upregulated in the rapid-recurrence group of chordoma, narrowed down by bioinformatics analysis, and finally potential biomarker was chosen for validation by immunohistochemistry using tissue microarray.

Project description:Chordoma is a rare primary bone malignancy that arises in the skull base, spine and sacrum and originates from remnants of the notochord. These tumors are typically resistant to conventional chemotherapy, and to date there are no FDA-approved agents to treat chordoma. The lack of in vivo models of chordoma has impeded the development of new therapies for this tumor. Primary tumor from a sacral chordoma was xenografted into NOD/SCID/IL-2R γ-null mice. The xenograft is serially transplantable and was characterized by both gene expression analysis and whole genome SNP genotyping. The NIH Chemical Genomics Center performed high-throughput screening of 2,816 compounds using two established chordoma cell lines, U-CH1 and U-CH2B. The screen yielded several compounds that showed activity and two, sunitinib and bortezomib, were tested in the xenograft. Both agents slowed the growth of the xenograft tumor. Sensitivity to an inhibitor of IκB, as well as inhibition of an NF-κB gene expression signature demonstrated the importance of NF-κB signaling for chordoma growth. This serially transplantable chordoma xenograft is thus a practical model to study chordomas and perform in vivo preclinical drug testing. Total five microarray experiments were conducted, two of which are for chordoma xenograft sammples and three for chrodoma primary tumor. RNA extracted from xenograft samples and from chordomas was hybridized to Illumina arrays.

Project description:Oncogenic transformation of individual cell fates by developmental signaling cascades and transcription factors triggers diverse cancer types. Chordoma is a rare, aggressive tumor arising from transformed notochord remnants. Various potentially oncogenic factors have been found deregulated in chordoma and its metastases, yet clear causation remains uncertain. In particular, expression of the notochord-controlling transcription factor Brachyury is hypothesized as key molecular driver in chordoma formation, yet an in vivo model to causally test its oncogenic potential in the notochord is missing. Here, we apply a zebrafish model of chordoma onset to identify the notochord-transforming potential of tumor-implicated candidate genes in vivo. We find that overexpression of human and zebrafish Brachyury, including a version with augmented transcriptional activity, is insufficient to initiate notochord hyperplasia in vivo. In contrast, the repeatedly chordoma-implicated receptor tyrosine kinase (RTK) genes EGFR and KDR/VEGFR2 are sufficient to transform developmental notochord cells, akin to direct activation of Ras. Analysis of transcriptome and sub-cellular organization from transformed notochords suggests that aberrant activation of RTK/Ras signaling attenuates processes required for the differentiation of notochord cells. Taken together, our results provide first in vivo indication for a lack of tumor-initiating potential of Brachyury expression in the notochord, and suggest activated RTK signaling as potent hyperplasia-initiating event in chordoma.

Project description:Chordoma is a rare primary bone malignancy that arises in the skull base, spine and sacrum and originates from remnants of the notochord. These tumors are typically resistant to conventional chemotherapy, and to date there are no FDA-approved agents to treat chordoma. The lack of in vivo models of chordoma has impeded the development of new therapies for this tumor. Primary tumor from a sacral chordoma was xenografted into NOD/SCID/IL-2R γ-null mice. The xenograft is serially transplantable and was characterized by both gene expression analysis and whole genome SNP genotyping. The NIH Chemical Genomics Center performed high-throughput screening of 2,816 compounds using two established chordoma cell lines, U-CH1 and U-CH2B. The screen yielded several compounds that showed activity and two, sunitinib and bortezomib, were tested in the xenograft. Both agents slowed the growth of the xenograft tumor. Sensitivity to an inhibitor of IκB, as well as inhibition of an NF-κB gene expression signature demonstrated the importance of NF-κB signaling for chordoma growth. This serially transplantable chordoma xenograft is thus a practical model to study chordomas and perform in vivo preclinical drug testing. The copy number and allelic balance pattern of a novel human chordoma xenograft samples was determined with Illumina BeadChips.

Project description:Patient-derived xenografts retain the genotype of the parent tumors more readily than tumor cells maintained in culture. The two reported clival chordoma xenografts are derived from recurrent tumors after radiation. In order to study the genetics of clival chordoma in the absence of prior radiation we sought to establish a patient-derived xenograft at primary resection of a clival chordoma.