Project description:In this study, a series of 102 cartilage tumors was used to uncover the molecular diversity of chondrosarcomas through the profiling of mRNA, miRNA, DNA methylation, DNA copy number aberrations and point mutations. An integrated classification using multiple molecular dimensions revealed three major molecular features unraveling the diversity in clinical outcome of chondrosarcoma: a high mitotic state, regional 14q32 loss of expression and IDH mutations leading to genome-wide hypermethylation. These three robust and simple molecular features classify chondrosarcoma in subtypes with superior clinical value as compared to the current grading system.

Project description:The purpose of this study was to characterize the histologic development of OA in a mouse model where OA is induced by destabilization of the medial meniscus (DMM model) and to identify genes regulated during different stages of the disease, using RNA isolated from the joint M-bM-^@M-^\organM-bM-^@M-^] and analyzed using microarrays.427 genes from the microarrays passed consistency and significance filters. There was an initial up-regulation at 2 and 4 weeks of genes involved in morphogenesis, differentiation, and development, including growth factor and matrix genes, as well as transcription factors including Atf2, Creb3l1, and Erg. Most genes were off or down-regulated at 8 weeks with the most highly down-regulated genes involved in cell division and the cytoskeleton. Gene expression increased at 16 weeks, in particular extracellular matrix genes including Prelp, Col3a1 and fibromodulin.The results support a phasic development of OA with early matrix remodelling and transcriptional activity followed by a more quiescent period that is not maintained. A group of 9 mice was used for collection of RNA at time 0 (before surgery) when the animals were 12 weeks old. For the other time points, 9 DMM and 9 sham controls were sacrificed at 2, 4, 8, and 16 weeks after surgery for RNA isolation. The tissue included tibial plateau and femoral condyle articular cartilage, subchondral bone with any osteophytes, meniscus, and the joint capsule with synovium was used for RNA isolation. The tissue was treated with RNAlaterM-BM-. (Invitrogen) prior to freezing and storage at -800 C. RNA was extracted by homogenization using the Precellys 24 tissue homogenizer (Bertin Technologies purchased from MO BIO) and the amount and quality of the RNA was determined using an Agilent 2100 Bioanalyzer. RNA was pooled prior to microarray analysis such that 3 randomly selected samples from each surgical group and time point were pooled to create each biological replicate. Because 9 mice were used for each experimental group, a total of three biological replicates per group were analyzed using the Affymetrix Mouse Genome 430 2.0 oligonucleotide arrays as described. One replicate pool, which was from week two DMM mice, did not meet the RNA integrity level needed for microarray analysis; thus, this pool was not analyzed further, leaving two pools for the week two DMM mice.

Project description:In this study, a series of 102 cartilage tumors was used to uncover the molecular diversity of chondrosarcomas through the profiling of mRNA, miRNA, DNA methylation, DNA copy number aberrations and point mutations. An integrated classification using multiple molecular dimensions revealed three major molecular features unraveling the diversity in clinical outcome of chondrosarcoma: a high mitotic state, regional 14q32 loss of expression and IDH mutations leading to genome-wide hypermethylation. These three robust and simple molecular features classify chondrosarcoma in subtypes with superior clinical value as compared to the current grading system.

Project description:In this study, a series of 102 cartilage tumors was used to uncover the molecular diversity of chondrosarcomas through the profiling of mRNA, miRNA, DNA methylation, DNA copy number aberrations and point mutations. An integrated classification using multiple molecular dimensions revealed three major molecular features unraveling the diversity in clinical outcome of chondrosarcoma: a high mitotic state, regional 14q32 loss of expression and IDH mutations leading to genome-wide hypermethylation. These three robust and simple molecular features classify chondrosarcoma in subtypes with superior clinical value as compared to the current grading system.

Project description:The main active metabolite of Vitamin A, all-trans retinoic acid (RA), is responsible for proper cellular function and tissue organization. The role of RA has been extensively studied in development, but there is limited research on its role in the adult heart. Cellular retinol-binding protein, type 1 (CRBP1), encoded by retinol-binding protein, type 1 (Rbp1), regulates RA homeostasis by delivering vitamin A to enzymes for RA synthesis. An animal model of CRBP1 deficiency, such as Rbp1–/– mice, can provide insight into disrupted RA biosynthesis and signaling. In this work, a multi-omics approach was used to characterize the effect of CRBP1 loss. Retinoid homeostasis was disrupted in Rbp1-/- mouse heart tissue, as seen by a 33% and 24% decrease in RA levels in the left and right ventricles, respectively, compared to wild-type mice (WT). To further inform on the effect of disrupted RA homeostasis, we conducted high-throughput targeted metabolomics. A total of 222 metabolite and metabolite combinations were analyzed, with 33 having differential expression between Rbp1-/- and WT hearts. Additionally, we performed global proteome profiling to further characterize the impact of CRBP1 loss in adult mouse hearts. More than 2,606 unique proteins were identified, with 340 proteins having differential expression between Rbp1-/- and WT hearts. Pathway analysis performed on metabolomic and proteomic data revealed pathways related to cellular metabolism and cardiac metabolism were the most disrupted in Rbp1-/- mice. Together, these studies provide data for establishing the effect of dysregulated RA signaling in the adult mouse heart.

Project description:Here we have used four enchondromas and two chondrosarcomas of Maffucci patients. We also had one normal sample available for paired analysis in one of the chondrosarcoma II. We did not find any LOH or coomon copy number variation in all Maffucci enchondromas while chondrosarcomas are genetically unstable. Affymetrix SNP 6.0 array was performed using 4 EC and 2CS of Maffucci patients. Illumina expression v3 array was possible to perform using only 1 EC and 2 CS due to rarity of the disease. For SNP array, we used 29 control samples submitted previously (GSE22965) to creat baseline.

Project description:Short-term starvation (STS or fasting) provides protection to normal cells, mice, and possibly patients from a variety of chemotherapy drugs, but the possibility that it may also protect tumor cells renders its translational potential uncertain. Here we show that fasting cycles can be as effective as toxic chemotherapy drugs, and increase chemotherapy efficacy in the treatment of melanoma, glioma, breast cancer, and neuroblastoma. In vitro, STS sensitizes to chemotherapy 15 of the 17 cancer cell lines tested. In combination with chemotherapy STS results in a synergistic 20-fold increase in DNA damage, increased phosphorylation of pro-aging genes AKT and S6 kinase, reduced expression of stress resistance transcription factors FOXO3a and NFkB, elevated superoxide, and activated caspase-3; all changes not observed in normal tissues. Several of these effects are linked to the activity of heme oxygenase 1 (HO-1), whose modulation was sufficient to regulate chemotherapy-dependent cell death in breast cancer cells. These studies suggest that multiple fasting cycles have the potential to replace certain toxic chemotherapy drugs and to sensitize a wide range of tumors to chemotherapy. To obtain an unbiased view of the gene expression changes occurring in cancer cells in response to fasting, we performed genome-wide microarray analyses, using Illumina's Sentrix MouseRef-8 v2 Expression BeadChips (Illumina, San Diego, CA), on the subcutaneous 4T1 breast cancer tumor mass, heart, muscle and liver tissues from balb-c mice that were either fasted for 48 hours or fed an ad lib diet. Three mice from each of the starvation and the ad lib fed groups were used for the array studies.

Project description:We performed quantitative and qualitative proteomic analysis by nanoLC-MS/MS to describe the proteomic phenotype of the heart and plasma in a rat model of diet-induced developmental obesity with an evaluation of whether the cardiac proteome is shaped by weight loss

Project description:DNA methylation profiling of normal prostates from organ donors and prostate cancer metastases from a rapid autopsy cohort of lethal metastatic prostate cancer Multiple anatomically distinct metastases from each of five patients. Normal prostate samples from organ donors

Project description:Energy metabolism and extracellular matrix function are closely connected to orchestrate and maintain tissue organization, but the crosstalk is poorly understood. Here, we used scRNA-seq analysis to uncover the importance of respiration for extracellular matrix homeostasis in mature cartilage. Genetic inhibition of respiration in cartilage results in the expansion of a central area of 1-month-old mouse femur head cartilage showing disorganized chondrocytes and increased deposition of extracellular matrix material. scRNA-seq analysis identified a cluster-specific decrease in mitochondrial DNA-encoded respiratory chain genes and a unique regulation of extracellular matrix-related genes in nonarticular chondrocyte clusters. These changes were associated with alterations in extracellular matrix composition, a shift in the collagen/non-collagen protein content and an increase of collagen crosslinking and ECM stiffness. The results demonstrate, based on findings of the scRNA-seq analysis, that respiration is a key factor contributing to ECM integrity and mechanostability in cartilage and presumably also in many other tissues.