Project description:Osteogenesis Imperfecta is characterized by short stature however the cellular mechanisms behind this phenotype are unclear. We isolated tibial and femoral cartilage growth plate chondrocytes from postnatal day 5 wild type and Aga2 (a model of OI) mice and analyzed differential expression patterns using single cell RNA-seq

Project description:Progressive mitochondrial respiratory chain (RC) deficiency is associated with a wide spectrum of adult-onset degenerative diseases, as well as with normal aging. We have previously generated the Deletor mice to model late-onset progressive RC defects. Here we report novel tissue-specific pathways contributing to mitochondrial disease pathogenesis, identified by gene expression analysis. We found that RC-deficient muscle fibers secrete the fasting-induced hormone, fibroblast growth factor 21 (FGF21). This response leads to fatty acid recruitment from adipocytes and resistance to high-fat-diet induced obesity in mice, but does not affect glucose or insulin metabolism. FGF21 is also induced in the muscle of mitochondrial myopathy patients and in other RC-deficient mice. These data show that skeletal muscle is an endocrine organ, which signals its energy deficiency through FGF21. Furthermore, RC deficiency in single muscle fibers initiates a global starvation response. These data have important implications for conditions with primary or secondary RC deficiency. Mice overexpressing mutant Twinkle (C10ORF2) protein are the first animal model for Progressive External Ophtalmoplegia (PEO). Using PEO-model and wt-mice, skeletal muscle (quadriceps femoris) was analyzed for gene expression profile.

Project description:Primary mitochondrial respiratory chain (RC) diseases are heterogeneous in etiology and manifestations but collectively impair cellular energy metabolism. To identify a common cellular response to RC disease, systems biology level transcriptome investigations were performed in human RC disease skeletal muscle and fibroblasts. Global transcriptional and post-transcriptional dysregulation in a tissue-specific fashion was identified across diverse RC complex and genetic etiologies. RC disease muscle was characterized by decreased transcription of cytosolic ribosomal proteins to reduce energy-intensive anabolic processes, increased transcription of mitochondrial ribosomal proteins, shortened 5'-UTRs to improve translational efficiency, and stabilization of 3'-UTRs containing AU-rich elements. These same modifications in a reversed direction typified RC disease fibroblasts. RC disease also dysregulated transcriptional networks related to basic nutrient-sensing signaling pathways, which collectively mediate many aspects of tissue-specific cellular responses to primary RC disease. These findings support the utility of a systems biology approach to improve mechanistic understanding of mitochondrial RC disease. To identify a common cellular response to primary RC that might improve mechanistic understanding and lead to targeted therapies for human RC disease, we performed collective transcriptome profiling in skeletal muscle biopsy specimens and fibroblast cell lines (FCLs) of a diverse cohort of human mitochondrial disease subjects relative to controls. Systems biology investigations of common cellular responses to primary RC disease revealed a collective pattern of transcriptional, post-transcriptional and translational dysregulation occurring in a highly tissue-specific fashion. Affymetrix Human Exon 1.0ST microarray analysis was performed on 29 skeletal muscle samples and Fibroblast cell lines from mitochondrial disease patients and age- and gender-matched controls.

Project description:Differential ageing of growth plate cartilage determines skeletal proportions

Project description:Chondrocytes at different maturation states in the growth plate produce matrix vesicles (MVs), membrane organelles found in the extracellular matrix, with a wide range of contents, such as matrix processing enzymes and receptors for hormones. We have shown that MVs harvested from growth zone (GC) chondrocyte cultures contain abundant small RNAs, including miRNAs. Here, we determined whether RNA also exists in MVs produced by less mature resting zone (RC) chondrocytes and, if so, whether it differs from the RNA in MVs produced by GC cells. Our results showed that RNA, small RNA specifically, was present in RC-MVs, and it was well-protected from RNase by the phospholipid membrane. A group of miRNAs was enriched in RC-MVs compared RC-cells, suggesting that miRNAs are selectively packaged into MVs. High throughput array and RNA sequencing showed that ~39% miRNAs were differentially expressed between RC-MVs and GC-MVs. Individual RT-qPCR also confirmed that miR-122-5p and miR-150-5p were expressed at significantly higher levels in RC-MVs compared to GC-MVs. This study showed that growth plate chondrocytes at different differentiation stages produce different MVs with different miRNA contents, further supporting extracellular vesicle miRNAs play a role as “matrisomes” that mediate the cell–cell communication in cartilage and bone development.

Project description:Progressive mitochondrial respiratory chain (RC) deficiency is associated with a wide spectrum of adult-onset degenerative diseases, as well as with normal aging. We have previously generated the Deletor mice to model late-onset progressive RC defects. Here we report novel tissue-specific pathways contributing to mitochondrial disease pathogenesis, identified by gene expression analysis. We found that RC-deficient muscle fibers secrete the fasting-induced hormone, fibroblast growth factor 21 (FGF21). This response leads to fatty acid recruitment from adipocytes and resistance to high-fat-diet induced obesity in mice, but does not affect glucose or insulin metabolism. FGF21 is also induced in the muscle of mitochondrial myopathy patients and in other RC-deficient mice. These data show that skeletal muscle is an endocrine organ, which signals its energy deficiency through FGF21. Furthermore, RC deficiency in single muscle fibers initiates a global starvation response. These data have important implications for conditions with primary or secondary RC deficiency.

Project description:Progressive mitochondrial respiratory chain (RC) deficiency is associated with a wide spectrum of adult-onset degenerative diseases, as well as with normal aging. We have previously generated the Deletor mice to model late-onset progressive RC defects. Here we report novel tissue-specific pathways contributing to mitochondrial disease pathogenesis, identified by gene expression analysis. We found that RC-deficient muscle fibers secrete the fasting-induced hormone, fibroblast growth factor 21 (FGF21). This response leads to fatty acid recruitment from adipocytes and resistance to high-fat-diet induced obesity in mice, but does not affect glucose or insulin metabolism. FGF21 is also induced in the muscle of mitochondrial myopathy patients and in other RC-deficient mice. These data show that skeletal muscle is an endocrine organ, which signals its energy deficiency through FGF21. Furthermore, RC deficiency in single muscle fibers initiates a global starvation response. These data have important implications for conditions with primary or secondary RC deficiency.

Project description:Articular and growth plate cartilage have comparable structures consisting of three distinct layers of chondrocytes, suggesting similar differentiation programs and therefore similar gene expression profiles. To address this hypothesis and to explore transcriptional changes that occur during the onset of articular and growth plate cartilage divergence, we used microdissection of 10-day-old rat proximal tibial epiphyses, microarray analysis, and bioinformatics to compare gene expression profiles in individual layers of articular and growth plate cartilage. We found that many genes that were spatially upregulated in intermediate/deep zone of articular cartilage were also spatially upregulated in resting zone of growth plate cartilage (overlap greater than expected by chance, P < 0.001). Interestingly, superficial zone of articular cartilage showed an expression profile with similarities to both proliferative and hypertrophic zones of growth plate cartilage (P < 0.001 each). Additionally, significant numbers of known proliferative zone markers (3 out of 6) and hypertrophic zone markers (27 out of 126) were spatially upregulated in superficial zone compared to intermediate/deep zone (more than expected by chance, P < 0.001 each). In conclusion, we provide evidence that intermediate/deep zone of articular cartilage has a gene expression profile more similar to resting zone of growth plate cartilage, whereas superficial zone has a gene expression profile more similar to proliferative and hypertrophic zones.

Project description:The aim of the current study was to identify molecular markers for articular cartilage that can be used for the quality control of tissue engineered cartilage. Therefore a genom-wide expression analysis was performed using RNA isolated from articular and growth plate cartilage, both extracted from the knee joints of minipigs. Keywords: Native material or primary cells isolated from articular cartilage and growth plate cartilage

Project description:Skeletal growth promoted by endochondral ossification is tightly coordinated by self-renewal and differentiation of chondrogenic progenitors. Emerging evidence has shown that multiple skeletal stem cells (SSCs) participate in cartilage formation. However, as yet, no study has reported the existence of common long-lasting chondrogenic progenitors in various types of cartilage. Here, we identified Gli1+ chondrogenic progenitors (Gli1+ CPs), which were distinct from SSCs, were responsible for the lifelong generation of chondrocytes in the growth plate, vertebrae, ribs, and other cartilage. The absence of Gli1+ CPs led to cartilage defects and dwarfishness phenotype in mice. Furthermore, we found that the BMP signal played an important role in self-renewal and maintenance of Gli1+ CPs. The deletion of Bmpr1α caused the exhaustion of Gli1+ CPs, consequently disrupting columnar cartilage. Collectively, our data demonstrate that Gli1+ CPs are common long-term chondrogenic progenitors in multiple types of cartilage and are essential to maintain cartilage homeostasis.