Project description:Maintenance of proper phenotypic state of mammary epithelial cells is crucial for normal function, however the molecular networks underlying control of various cellular phenotypes are not well understood. To date most studies have assessed the impact of extracellular signals on a single phenotypic response, such as proliferation, or have focused on elucidation of molecular changes associated with single perturbations. However, these approaches ignore that ligands frequently induce multiple phenotypic changes and that similar phenotypic responses can be induced by multiple ligands. As a consequence, little is known about the core molecular mechanisms that drive cells to different phenotypic states. Here we deeply profiled the phenotypic and molecular responses of MCF10A mammary epithelial cells to a diverse panel of ligands known to have a role in the normal mammary gland. These ligands elicited multiple phenotypic responses, including changes in proliferation, migration, and differentiation status. Analysis of companion RNAseq, ATACseq, and proteomic data identified distinct molecular features associated with ligand treatments and phenotypic changes. These data provide a robust resource to address questions about how environmental signals are encoded into molecular and phenotypic responses, the associations between molecular modalities, and temporal encoding of molecular and phenotypic responses. 

Project description:Phase I/II clinical trial investigates the safety, tolerability, immunogenicity and preliminary efficacy of multiple doses of PolyPEPI1018 CRC vaccine as an add-on treatment to the standard-of-care maintenance therapy in patients with metastatic colorectal cancer. Clinical responses will be evaluated by indiction of T cell responses, T lymphocyte infiltration in accessible biopsy sites, and by objective tumor responses. This study will also explore the accuracy of the predicted T cell responses in each patient using the candidate companion diagnostic test and the correlations between clinical responses and predicted T cell responses.

Project description:Purpose: analyze ligand and receptor genes regulated at early time points following JAK STAT pathway stimulation During development and homeostasis, cells integrate multiple signals originating either from neighboring cells or systemically. In turn, responding cells can produce signals that act in an autocrine, paracrine, or endocrine manner. Although the nature of the signals and pathways used in cell-cell communication are well characterized, we lack, in most cases, an integrative view of signaling describing the spatial and temporal interactions between pathways (e.g., whether the signals are processed sequentially or concomitantly when two pathways are required for a specific outcome). To address the extent of cross-talk between the major metazoan signaling pathways, we characterized immediate transcriptional responses to either single- or multiple pathway stimulations in homogeneous Drosophila cell lines. Our study, focusing on seven core pathways, epidermal growth factor receptor (EGFR), bone morphogenetic protein (BMP), Jun kinase (JNK), JAK/STAT, Notch, Insulin, and Wnt, revealed that many ligands and receptors are primary targets of signaling pathways, highlighting that transcriptional regulation of genes encoding pathway components is a major level of signaling cross-talk. In addition, we found that ligands and receptors can integrate multiple pathway activities and adjust their transcriptional responses accordingly. RNA-seq data is for JAK STAT pathway only

Project description:Molecular and phenotypic changes in FLExDUX4 mice

Project description:please ignore this

Project description:Wnt signaling in early eye development, specifically the lens placode shows expression of 12 out of 19 Wnt ligands. We these Wnt activities were suppressed using conditional deletion of Wntless, dramatic phenotypic changes in morphogensis occurred. Microarray analysis of the genes that were changed in response to deletion of Wnt ligands in the developing eye region show direct or indirect responses from the surface ectoderm to the developing RPE and optic cup curvature, creating an overal shape change phenotype in the bilayerd epithelium of the optic cup.

Project description:Resolution of genome-wide molecular signals in canine mammary tumor model

Project description:Breast cancer is the most frequent cancer among women causing the greatest number of cancer-related deaths. Cancer heterogeneity is a main obstacle to therapies. Around 96% of the drugs fail from discovery to the clinical trial phase probably because of the current unreliable preclinical models. New models emerge such as companion dogs who develop spontaneous mammary tumors resembling human breast cancer in many clinical and molecular aspects. The present work aimed at developing a robust canine mammary tumor model in the form of tumoroids which recapitulate the tumor diversity and heterogeneity. We conducted a complete characterization of these canine mammary tumoroids through histologic, molecular and proteomic analysis, demonstrating their strong similarity to the primary tumor. We demonstrated that these tumoroids can be used as a drug screening model. Due to easy tissue availability, tumoroids can be produced at larger scale and cryopreserved to constitute a biobank. We have demonstrated that cryopreserved tumoroids keep the same histologic and molecular features (ER, PR and HER2 expression) as fresh tumoroids. Two techniques of cryopreservation were compared demonstrating that tumoroids made from frozen tumor material allowed to maintain a higher molecular diversity. These findings revealed that canine mammary tumoroids can be easily generated at large scale and can represent a more reliable preclinical model to investigate tumorigenesis mechanisms and develop new treatments for both veterinary and human medicine.

Project description:Marginal zone (MZ) B cells leverage Notch2 signals to attain rapid differentiation responses and positional cues with in the spenic environment.To determine the likely molecular source of Notch2 signals we sought to block the Notch ligands delta-like ligand 1 (Dll1) and delta-like ligand 4 (Dll4) in wildtype mice using in-vivo treatment with monoclonal blocking antibodies. Splenic populations of MZ B cells and follicular B cells were sort purified after 12, 24 and 48 hours of blockade and analyzed by RNA-seq.

Project description:The activation of receptors displayed on the surface of cells typically initiates cytoplasmic signalling cascades that lead to changes in cellular transcriptional responses so that a cell expresses proteins that enable it to behave appropriately as a function of their position within an organism. Understanding these signals and learning how to either prevent or ectopically activate them could have many therapeutic benefits and applications. In some cases these signals are highly localised, being delivered by directly neighbouring cells that express ligands which specifically bind to and activate receptors; for example, stem cells display receptors for ligands provided by cells within their niche to both ensure continual production of cells, and that their cellular progeny are directed towards appropriate fates. While for some cell types we know something of these signals enabling the in vitro differentiation of stem cells towards certain cellular fates, the differentiation processes is often not complete and so immature cell types which are not fully functional are produced, implying that some important signals are missing. Here, we propose to systematically identify receptor-triggered signalling pathways by stimulating receptors on the surface of human stem cells by using a library of soluble recombinant oligomerised protein ligands and measuring the consequent transcriptional perturbations using RNA-seq. We propose to screen an existing library of ~50 oligomerised human ligands previously used in receptor protein interaction screens and first test them for their ability to bind to human stem cells to identify those ligands for which the stem cells express a cell surface receptor. For those ligands which interact with the stem cells (we estimate between 2 and 5), they will be added to stem cell cultures and their effects on transcription quantified. The budget requested is sufficient for us to include controls and test important parameters such different time points after addition of the proteins. 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/