Project description:The avascular nature of cartilage makes it a unique tissue in the human body, but whether and how the absence of blood vessels regulates chondrogenesis remains unknown. Obstruction of vascular invasion during bone healing favours chondrogenic over osteogenic differentiation of skeletal progenitor cells, a process we observed to be driven by a decreased availability of extracellular lipids. To understand how lipid deprivation activates the chondrogenic programme, we profiled mRNA expression of C3H10T1/2 skeletal progenitors exposed to lipid deprivation for 1, 3 or 6 hours.

Project description:Objective: Skeletal stem cells are known to be regulated by their local self-regulating niche, that is comprised mainly of their progeny and secreted paracrine factors. What cell intrinsic factors govern the maintenance and function of the SSC remains elusive. Methods: Using the previously characterized Tet1-/- mice we investigated the differences in skeletal stem cell lineage tree. Further we examined the ability of these cells to differentiate into osteogenic and chondrogenic lineages, both with and without injury. Transcriptomic differences and inflammatory cytokines were investigated for differences in cartilage development pathways. Results: Loss of Tet1 skews the SSC lineage tree by expanding the SSC pool at the expense of its progeny as well as by enhancing the chondrogenic differentiation of SSC and the multilineage bone cartilage stromal progenitors (BCSP). Tet1 inhibition leads to enhanced chondrogenesis in mouse BCSP upon injury, in human SSC and chondroprogenitors (CP) isolated from osteoarthritic (OA) human cartilage and in late stages of OA in a mouse model. Transcriptomic analyses of SSC and BCSP lacking Tet1 revealed dysregulated pathways including alterations in Tgfb signaling, melatonin degradation and cartilage development associated genes. Conclusion: Tet1 was identified as critical regulator of SSC fate. Loss of Tet1 selectively enhances chondrogenic ability of skeletal stem cells. Supplementation of melatonin can dampen inflammation and lead to better cartilage health.

Project description:The regeneration of diseased hyaline cartilage remains a great challenge, mainly because degeneration activities after major injury or due to age-related processes overwhelm the self-renewal capacity of the tissue. We show that repair tissue from human articular cartilage of late stages of osteoarthritis harbor a unique progenitor cell population, termed chondrogenic progenitor cells exhibiting stem cell characteristics, such as multipotency, lack of immune system activation and, in particular, migratory activity. The isolated CPC exhibit a high chondrogenic potential and were able to populate diseased tissue in vivo. Moreover, down-regulation of the osteogenic transcription factor runx-2 enhanced the expression of the chondrogenic transcription factor sox-9 and consequently the matrix synthesis potential of chondrogenic progenitor cells. Our results, while offering new insight into the biology of progenitor cells from diseased cartilage tissue, might assist future strategies to treat late stages of osteoarthritis. Experiment Overall Design: Characterization chondrogenic progenitor cells in P1 of 3 male and 3 female patients with late-stage OA in comparison to healthy chondrocytes in P1

Project description:The regeneration of diseased hyaline cartilage remains a great challenge, mainly because degeneration activities after major injury or due to age-related processes overwhelm the self-renewal capacity of the tissue. We show that repair tissue from human articular cartilage of late stages of osteoarthritis harbor a unique progenitor cell population, termed chondrogenic progenitor cells exhibiting stem cell characteristics, such as multipotency, lack of immune system activation and, in particular, migratory activity. The isolated CPC exhibit a high chondrogenic potential and were able to populate diseased tissue in vivo. Moreover, down-regulation of the osteogenic transcription factor runx-2 enhanced the expression of the chondrogenic transcription factor sox-9 and consequently the matrix synthesis potential of chondrogenic progenitor cells. Our results, while offering new insight into the biology of progenitor cells from diseased cartilage tissue, might assist future strategies to treat late stages of osteoarthritis. Keywords: cell type comparison

Project description:The identity of cells that establish the hematopoietic microenvironment (HME) in human bone marrow (BM), and of skeletal ("mesenchymal") stem cells (SSCs) found in BM stroma, have long remained elusive. We show that MCAM/CD146-expressing, subendothelial cells in human BM stroma are both the self-renewing SSCs and the cells that transfer the HME at heterotopic sites upon transplantation. Establishment and self-renewal of SSCs in developing BM in vivo occurs via specific, dynamic interactions with developing sinusoids. Non-differentiated SSCs residing on the sinusoidal wall, but not differentiated osteoblasts, express Angiopoietin-1 (a pivotal molecule of the HSC "niche" involved in vascular remodeling). Our data reveal the functional relationships between establishment of the HME in vivo, establishment of SSCs in BM sinusoids, and angiogenesis. Experiment Overall Design: The series is composed by 7 samples hybridized to Affymetrix GeneChips. 4 of these samples (A18, A22, A23 e A27) are different clones of mesenchymal stem cells, while the other 3 represent different treatments of one of these clones with specific growth factors.

Project description:Transcriptional profiling of mouse spermatogonial stem cells (SSCs) comparing control untreated SSCs with SSCs with exogenous FGF2 withdrawn and FGFR inhibitor SU5402 supplemented (-F+S). Results provide insight into the mechanisms of FGF2-supported in vitro self-renewal of SSCs. Two-condition experiment, SSCs-F+S vs. SSCs. Biological replicates: 4 control replicates, 4 -F+S replicates.

Project description:Mutations in the RMRP gene are the origin of cartilage-hair hypoplasia. Cartilage-hair hypoplasia is associated with severe dwarfism caused by impaired skeletal development. However, it is not clear why mutations in the RMRP gene lead to skeletal dysplasia. Viperin is a known substrate of RMRP. Since chondrogenic differentiation of the growth plate is required for development of the long bones, we hypothesized that viperin functions as a chondrogenic regulator downstream of RMRP. Viperin protein is expressed throughout the stages of chondrogenic differentiation in vivo. Viperin gene expression is increased during knockdown of Rmrp RNA in the ATDC5 model for chondrogenic differentiation. Viperin is expressed during ATDC5 chondrogenic differentiation. Viperin knockdown reduces, while viperin overexpression increases overall protein secretion, with CXCL10 identified as a potential target via mass spectrometry-proteomics. CXCL10 protein expression is reduced during knockdown and increased during overexpression of viperin and CXCL10 protein expression coincides with viperin expression in ATDC5 chondrogenic differentiation. Viperin knockdown induces, while viperin overexpression reduces TGFβ activity. Furthermore, viperin knockdown conditioned media increases, while viperin overexpression conditioned media reduces chondrogenic differentiation of ATDC5 cells. TGFβ target genes Pai1 and Smad7 are increased during knockdown and reduced during overexpression of viperin. Moreover, TGFβ activity is reduced when differentiating ATDC5 cells are exposed to CXCL10 and, acting as a viperin overexpression mimic, CXCL10 similarly reduces chondrogenic differentiation of ATDC5. Lastly, we show that in CHH patient cells, RMRP expression is reduced and viperin expression is increased, coinciding with reduced chondrogenic differentiation and increased CXCL10 expression, possibly explaining the CHH phenotype. Together our data show that viperin may play a pivotal role in chondrogenic differentiation, with potential consequences for cartilage-hair hypoplasia pathobiology.

Project description:The spermatogonial stem cells (SSCs) niche is critical for SSC maintenance and the subsequent spermatogenesis. Numerous reproductive hazards impair the SSC niche, thereby result in aberrant SSC self-renewal and male infertility. However, promising agents targeting the impaired SSC niche to promote SSC self-renewal are still limited. Here, we screen out and assess the effects of Lovastatin on the self-renewal of mouse spermatogonial stem cells (mSSCs). Mechanistically, Lovastatin promotes the self-renewal of mSSCs and inhibits its inflammation and apoptosis through the regulation of isoprenoid intermediates. Likewise, other statins  exhibit similar effects on SSC self-renewal. Remarkably, the treatment by Lovastatin could promote the self-renewal of mSSCs in the male gonadotoxicity model generated by busulfan injection. Noteworthy, we demonstrate that Lovastatin could significantly enhance the self-renewal of in vitro cultured primate SSCs. Collectively, our findings uncover that lovastatin could promote the self-renewal of both murine and primate SSCs and have implications for the treatment of certain male infertility using small compounds.

Project description:The identity of cells that establish the hematopoietic microenvironment (HME) in human bone marrow (BM), and of skeletal ("mesenchymal") stem cells (SSCs) found in BM stroma, have long remained elusive. We show that MCAM/CD146-expressing, subendothelial cells in human BM stroma are both the self-renewing SSCs and the cells that transfer the HME at heterotopic sites upon transplantation. Establishment and self-renewal of SSCs in developing BM in vivo occurs via specific, dynamic interactions with developing sinusoids. Non-differentiated SSCs residing on the sinusoidal wall, but not differentiated osteoblasts, express Angiopoietin-1 (a pivotal molecule of the HSC "niche" involved in vascular remodeling). Our data reveal the functional relationships between establishment of the HME in vivo, establishment of SSCs in BM sinusoids, and angiogenesis. Keywords: comparative genomics, genetic modification

Project description:To better understand human spermatogonial stem cells (SSCs), we profiled their transciptome and epigenome, which revealed the mechanism how human SSCs regulates their self-renewal versus differentiation dermination, as well as how latent pluripotency is established in human SSCs. Remarkly, we discovered signaling pathways (e.g. LIF, BMP, WNT) that differentially regulated self-renewal vesus differentiation in SSCs. We also discovered that SSCs repress core pluripotent factors (Sox2, Pou5f1 and Nanog) yet activate ancillary factors (e.g. Klf4, Mbd3, Tcf3, Sall4) transcriptionally and epigenetically.