Project description:Transcriptional profiling comparing adult wild-type indirect flight muscle (IFM) with wild-type leg muscle and salm RNAi IFM (Mef2-GAL4, UASsalmIR). We used 2 different salm hairpin constructs for the experiments, TF3029 and TF101052, both available from the VDRC Drosophila stock centre. Experiments were done in biological duplicates + 1 technical replicate (1 labeled sample was hybridized on a different array)

Project description:Background and Purpose: Cardiotoxicity is a well-known adverse effect of radiation therapy. Measurable abnormalities in the heart function indicate advanced and often irreversible heart damage. Therefore, early detection of cardiac toxicity is necessary to delay and alleviate the development of the disease. The present study investigated long-term serum proteome alterations following local heart irradiation using a mouse model with the aim to detect biomarkers of radiation-induced cardiac toxicity. Materials and Methods: Serum samples from C57BL/6J mice were collected 20 weeks after local heart irradiation with 8 Gy or 16 Gy X-ray; the controls were sham-irradiated. The samples were analyzed by quantitative proteomics based on data-independent acquisition mass spectrometry. The proteomics data were further investigated using bioinformatics and ELISA. Results: The analysis showed radiation-induced changes in the level of several serum proteins involved in the acute phase response, inflammation and cholesterol metabolism. We found significantly enhanced expression of pro-inflammatory cytokines (TNF-, TGF-, IL-1 and IL-6) in the serum of the irradiated mice. The level of free fatty acids, total cholesterol, low density lipoprotein (LDL) and oxidized LDL was increased whereas that of high density lipoprotein was decreased by irradiation. Conclusions: This study provides information on systemic effects of heart irradiation. It elucidates a radiation fingerprint in the serum that may be used to elucidate adverse cardiac effects after radiation therapy.

Project description:Murine ES-derived neural stem cells (NSC) were not irradiated (ctrl) or irradiated with 10Gy and cultured for 7 days (irr). The goal was to study the gene expression changes in NSC at d7 after irradiation. Total RNA was extracted from 4 ctrl and 4 irr samples (biological quadruplicates).

Project description:Osteosarcoma is the most common primary bone tumours of dogs. Canine osteosarcoma contains a sub-population of cancer stem cells. Here we used canine-specific microarrays to compare the global gene expression profiles of osteosarcoma stem cells to adherent cancer cells and canine mesenchymal stem cells. Canine osteosarcoma spheres were isolated by their ability to form tumourspheres. Spheres, adherent cells and mesenchymal stem cells were harvested and used for RNA extraction and hybridisation on Affymetrix microarrays (Canine 2.0). Four biological replicates of each sample were included.

Project description:Wistar rats, purchased from BRL (Fullinsdorf/BL, Switzerland), and WBN/Kob rats, purchased from SLC Inc. (Shizuoka, Japan), were specific pathogen-free. Rats were housed in groups of maximally 4 instandard cages (1,820 cm2 bottom area) and kept in our animal facility for various time periods between 1 week and 36 weeks (free access to standard rat chow and water; specific pathogen-free conditions; 20 degree C; day/night cycle simulated by artificial lighting of 50 lx from 7 a.m. to 7 p.m., dimmed in the remaining hours to almost complete darkness; air humidity 50 to 60%). Prior to surgery or sacrifice, the rats were fasted overnight (16 to18 h) with free access to water. All manipulations conformed with the Swiss Federal Guidelines on Animal Experiments and were approved by the local ethics committee.

Project description:Oncogenic signaling of the niche can have a severe effect on the hematopoietic compartment and could contribute or play an active role during the development of human leukemia predisposition syndromes. To provide insights into the mechanisms that underlie this concept, as well as their relevance to disease, this study uses the leukemia predisposition syndrome Shwachman-Diamond syndrome (SDS) as a model. This leukemia predisposition syndrome is established by constitutive homozygous or compound heterozygous loss-of-function mutations in the gene SBDS. SDS is characterized by skeletal defects and a striking predisposition for the development of myelodysplastic syndrome (MDS) and acute myeloid leukemia (AML). Loss of Sbds in the hematopoietic compartment does not results in the induction of MDS or AML, however, could have an indirect effect on the hematopoietic system through the disruption of niche cells.<br>This submission concerns itself with gene expression profiling of transgenic mice. Osterix1 (Osx) is a zinc-finger transcriptional factor essential for osteoblast differentiation in mice and is expressed in cells of the mesenchymal lineage. A bacterial artificial chromosome (BAC) was modified such that it expressed the green fluorescent protein (GFP)::Cre recombinase (GFP::Cre) fusion protein. The artificial construct was inserted into the Osterix gene (Osx1, Sp7), enabling fusion gene GFP::Cre to be expressed from the Osx promotor (Osx1-GFP::Cre) and thereby creating transgenic mice. Cells isolated from these mice are therefore termed Osx::GFP cells. The Osx-GFP-Cre mice were crossed with Sbds f/f (flox/flox, loxp sites are inserted into the gene Sbds enabling the deletion of the region located between these loxp sites) mice to generate the transgenic Osx-GFP-Cre Sbds f/f (OCS) mice. Hence cells expressing the Osx/Sp7 gene therefore express the GFP::Cre fusion protein which enables the prospective isolation of GFP+ cells and it enables the deletion of the Sbds gene through the Cre-mediated recombination of the loxp sites.</br><br> OCS mice have skeletal defects similar to those observed in the human leukemia predisposition syndrome SDS. To obtain a detailed understanding of the underlying mechanisms Osx::GFP+ cells were prospectively isolated from bone cells suspensions, through fluorescence activated cell sorting (FACS), derived from OCS mice. Mutant OCS mice have a homozygous deletion of the Sbds gene in mesenchymal cells (e.g., osteoblasts), while wildtype mice have normal Sbds alleles. The gene expression profiles (GEPs) of both groups of mice were directly compared to determine major transcriptional changes.</br>

Project description:Previously we reported that a recombinant vaccinia virus (VACV) carrying a light-emitting fusion gene enters, replicates in, and reveals the locations of tumors in mice. A new recombinant VACV, GLV-1h68, as a simultaneous diagnostic and therapeutic agent, was constructed by inserting three expression cassettes (encoding Renilla luciferase-green fluorescent protein (RUC-GFP) fusion, b-galactosidase, and b-glucuronidase) into the F14.5L, J2R (encoding thymidine kinase, TK), and A56R (encoding hemagglutinin, HA) loci of the viral genome, respectively. Intravenous (i.v.) injections of GLV-1h68 (1 × 107 pfu/mouse) into nude mice with established (500 mm3) subcutaneous (s.c.) GI-101A human breast tumors were used to evaluate its toxicity, tumor targeting specificity and oncolytic efficacy. GLV-1h68 demonstrated an enhanced tumor targeting specificity and much reduced toxicity compared to its parental LIVP strains. The tumors colonized by GLV-1h68 exhibited growth, inhibition, and regression phases followed by tumor eradication within 130 days in 95% of the mice tested. Tumor regression in live animals was monitored in real time based on decreasing light emission, hence demonstrating the concept of a combined oncolytic virus-mediated tumor diagnosis and therapy system. Transcriptional profiling of regressing tumors based on a mouse-specific platform revealed gene expression signatures consistent with immune defense activation, inclusive of interferon stimulated genes (STAT-1 and IRF-7), cytokines, chemokines and innate immune effector function. These findings suggest that immune activation may combine with viral oncolysis to induce tumor eradication in this model, providing a novel perspective for the design of oncolytic viral therapies for human cancers. Objective: To determine the gene expression changes induced by GLV-1h68 vaccinia virus injection in mouse carrying human breast cancer implant and leading to tumor eradication. Methods: Gene expression was analyzed using oligonucleotide microarrays. Responsiveness to vaccina virus injection was assessed by toxicity and survival study, gene expression anaysis and tumor volume change. Result: The tumors colonized by GLV-1h68 exhibited growth, inhibition, and regression phases followed by tumor eradication within 130 days in 95% of the mice tested. Tumor regression in live animals was monitored in real time based on decreasing light emission, hence demonstrating the concept of a combined oncolytic virus-mediated tumor diagnosis and therapy system. Transcriptional profiling of regressing tumors based on a mouse-specific platform revealed gene expression signatures consistent with immune defense activation, inclusive of interferon stimulated genes (STAT-1 and IRF-7), cytokines, chemokines and innate immune effector function. Conclusion: Our findings suggest that immune activation may combine with viral oncolysis to induce tumor eradication in this model, providing a novel perspective for the design of oncolytic viral therapies for human cancers. Experiment Overall Design: tumor tissues 3 and 6 weeks post virus injection

Project description:Tumors engender an environment dominated by M2 differentiated tumor macrophages that support tumor invasion, metastases and escape from immune control. In this study, we demonstrate that following radiation therapy of tumors in mice there is an influx of tumor macrophages that polarize towards wound repair and immune suppression. To investigate changes in the phenotype of tumor macrophages following radiation therapy, we FACS sorted tumor macrophages from Panc02 tumors. We have previously shown that we can distinguish mature tumor macrophages from immature myeloid and MDSC populations by expression of Gr1 and IA (MHC class II). To isolate these sub-populations, we first gated CD11b+ cells in the untreated or irradiated tumors, then sorted the CD11b+IA+ macrophage population and the CD11b+Gr1hi MDSC population. Cytospins of the sorted populations demonstrates that the CD11b+Gr1hi MDSC predominantly have a granulocyte morphology and the CD11b+IA+ cells have a macrophage morphology in both the untreated and irradiated tumors. RNA was purified from CD11b+IA+ macrophages from untreated or irradiated tumors 1 day or 7 days following radiation therapy and Gene Expression Microarray analysis was performed. There are untreated and irradiated samples at time points 1 day and 7 days following radiation therapy. The experiment was repeated in entirety, generating a second gene array sample for each. For analysis, the untreated samples of 1 day and 7 days were grouped together.

Project description:Ultraviolet-B (UVB) irradiation of the skin was performed on rat (skin and DRG) and human (skin) tissue. The resulting changes in gene expression were then profiled by using RNA-seq to compare gene expression between irradiated and non-irradiated samples Poly(A) selected RNA was sequenced for 5 irradiated and 4 non-irradiated humans (skin), and for 6 irradiated and 6 non-irradiated rats (DRG and skin)

Project description:This program aims at identifying a muscle gene signature associated with aging in rat sarcopenia model The profiling data was analyzed by identifying genes that were up- and down-regulated at selected p value and fold change in the muscle of aged rats compared to the young controls.