Project description:High-resolution shotgun proteomic analysis on two porcine collagen-based biomaterials designed for guided bone regeneration and soft tissue augmentation was perfomed. A porcine-derived collagen membrane and a collagen matrix derived from peritoneum and/or skin were digested, separated by nano-reverse-phase high-performance liquid chromatography, and peptides subjected to mass spectrometric detection and analysis

Project description:Porcine plantar skin was compared to 3 other skin types, namely trunk, snout and dorsal foot skin, to identify potential differences in gene expression profiles, which could lead to insights into the mechanisms underlying the many specializations of plantar skin tissue.

Project description:Differential gene expression between porcine plantar, trunk, dorsal foot, and snout skin

Project description:Foetal skin is known to heal without scar. This ability is lost in the third trimester of gestation. In mouse, scarless wound healing was reported until the day 15-16 of gestation. A range of factors that could explain the mechanisms of scarless skin wound healing have been identified, to mention reduced immune response, a greater proportion of collagen type III, hyaluronic acid and transforming growth factor beta isoform 3. The involvement of epigenetic changes, which are known to determine developmental processes, has not been examined in the context of scarless foetal skin healing so far. We performed the microarray analysis methylome and transcriptome of murine foetal dorsal skin at embryonic day 15 contrasted with those in later phases at embryonic days 18-19 as well as the in the adult mouse. The group of genes which show decreased methylation status in the foetal skin before the loss of ability to scarless healing between embryonic day 15 and 18 are enriched with transcriptional factors involved in embryonic morphogenesis, epithelium development, neuron differentiation, and synapse functions. The genes with increased methylation after the transition are associated with cell death and epithelial cell differentiation, inflammatory and wounding response and the degradation of hyaluronic acid. A substantial part of DNA methylation differences observed between embryonic day 15 and 18 were retained later at embryonic day 19 and in adults and remarkably correlated with gene expression changes. A major part of genes encoding the key factors responsible for cutaneous wound healing show significant changes in gene expression following the transition from scar free to normal healing. The results show that skin methylome and transcriptome undergoe extensive alterations following the loss of ability to scarless healing, while the functions associated with the changes imply their central role in skin wound repair.

Project description:Foetal skin is known to heal without scar. This ability is lost in the third trimester of gestation. In mouse, scarless wound healing was reported until the day 15-16 of gestation. A range of factors that could explain the mechanisms of scarless skin wound healing have been identified, to mention reduced immune response, a greater proportion of collagen type III, hyaluronic acid and transforming growth factor beta isoform 3. The involvement of epigenetic changes, which are known to determine developmental processes, has not been examined in the context of scarless foetal skin healing so far. We performed the microarray analysis methylome and transcriptome of murine foetal dorsal skin at embryonic day 15 contrasted with those in later phases at embryonic days 18-19 as well as the in the adult mouse. The group of genes which show decreased methylation status in the foetal skin before the loss of ability to scarless healing between embryonic day 15 and 18 are enriched with transcriptional factors involved in embryonic morphogenesis, epithelium development, neuron differentiation, and synapse functions. The genes with increased methylation after the transition are associated with cell death and epithelial cell differentiation, inflammatory and wounding response and the degradation of hyaluronic acid. A substantial part of DNA methylation differences observed between embryonic day 15 and 18 were retained later at embryonic day 19 and in adults and remarkably correlated with gene expression changes. A major part of genes encoding the key factors responsible for cutaneous wound healing show significant changes in gene expression following the transition from scar free to normal healing. The results show that skin methylome and transcriptome undergoe extensive alterations following the loss of ability to scarless healing, while the functions associated with the changes imply their central role in skin wound repair.

Project description:Systematic in vitro and in vivo characterization of Leukemia-inhibiting factor (LIF)- and Fibroblast growth factor (FGF) -derived porcine induced pluripotent stem cells (Cell reprogramming -basic developmental studies in the pig) vs Porcine embryonic stages (Plurisys) Global gene expression analyses and comparisons of LIF piPSC, FGF piPSC, Parental fibroblast line day 7-8 porcine embryo, day 10-11 porcine embryo, day 12-13 porcine embryo. Gene network analyses of piPSC lines, pNF and ICM from day 7-8 porcine embryos.

Project description:Murine GVH-SSc dorsal scapular skin samples were analyzed to determine the effect of IFNAR-1 inhibition on gene expression at day 14 and day 28. Gene expression in GVH-SSc skin from mice treated with a neutralizing IFNAR-1 antibody was compared to that in GVH-SSc skin from mice treated with isotype IgG, with skin from syngeneic graft controls as reference.

Project description:The dorsal and leg skin showed significant difference in skin thickness, feather follicle density and size.These traits are important characters of slaughtered chicken appearance. Global gene expression profiling was conducted in dorsal and leg skin of chickens, using the Agilent Chicken Gene Expression Chip. A total of 676 differentially expressed genes (DEGs) with at least 2-fold differences were identified (P < 0.05).GO analysis showed that DEGs were significantly involved in cell proliferation, differentiation, apoptotic, cell-cell adhesion and Wnt signaling pathway; KEGG pathway analyses found that DEGs were significantly mapped into ECM-receptor interaction, focal adhesion, Cell adhesion molecules (CAMs), regulation of actin cytoskeleton and Hedgehog signaling pathway.

Project description:We performed single-cell RNA seq on C57/BL6 mouse back skin at E13.5, E16.5, and P0 to study embryonic hair follicle development. We analyzed 15,086 single cell transcriptome profiles from E13.5, E16.5 and newborn mice (postnatal day 0, P0) dorsal skin cells across hair follicle induction, organogenesis, cytodifferentiation stage. Based on t-distributed Stochastic Neighbor Embedding (tSNE) clustering, we identified 14 cell clusters from skin cells and delineated their cell identity gene expression profile. By using Monocle pseudotime ordering analysis, we constructed epithelium/dermal cell lineage differentiation trajectory and revealed sequential activation of key regulons involved during embryonic hair follicle morphogenesis. Our findings here provide molecular landscape during hair follicle epithelium/dermal cell lineage fate decisions.

Project description:APs were isolated from naïve skin and day 5wounds from dorsal skin wound beds of 7-9 weeks old using FACS. This experiment describes changes in AP gene expression associated with injury and subsequent tissue repair.