Project description:Adaptive cellular reprogramming is an emerging field to study promotion of a host’s intrinsic healing strategies through changing one somatic cell type into another state or fate; tissue injury is known to enhance such cell conversions. Here we identify a molecular pathway in injured skin, whereby a subset of dermal fibroblasts displays a novel vasculogenic state change with gain in vasculogenic transcripts and endothelial cell-like functions without losing core fibroblast lineage fate phenotypic, functional, and transcriptional characteristics. Removal of microRNA suppression of FLI1 transcription in fibroblasts results in upregulation of a cascade of vasculogenic molecules that heralds the vasculogenic state change in some fibroblasts. FLI1 dependent vasculogenic fibroblast subset emergence in injured skin is blunted in poorly healing skin wounds of diabetic animals but can be restored through topical tissue nanotransfection of a single anti-microRNA oligonucleotide, to rescue tissue perfusion and wound healing. Augmenting a physiologic tissue injury adaptive response mechanism that produces vasculogenic fibroblasts opens new avenues for therapeutic tissue vascularization of ischemic conditions.

Project description:Development of treatments for vocal dysphonia has been inhibited by lack of human vocal fold (VF) mucosa models because of difficulty in procuring VF epithelial cells, epithelial cells’ limited proliferative capacity and absence of cell lines. We report development of engineered VF mucosae from hiPSC, transfected via TALEN constructs for green fluorescent protein, that mimic development of VF epithelial cells in utero. Modulation of FGF signaling achieves stratified squamous epithelium from definitive and anterior foregut derived cultures. Robust culturing of these cells on collagen-fibroblast constructs produces three-dimensional models comparable to in vivo VF mucosa. Second, we demonstrate mucosal inflammation upon exposure of these constructs to 5% cigarette smoke extract. Upregulation of pro-inflammatory genes in epithelium and fibroblasts leads to aberrant VF mucosa remodeling. Collectively, our results demonstrate that hiPSC-derived VF mucosa is a versatile tool for future investigation of genetic and molecular mechanisms underlying epithelium-fibroblasts interactions in health and disease.

Project description:CD34+ cells improve the perfusion and function of ischemic limbs in humans and mice. However, there is no direct evidence of the differentiation potential and functional role of these cells in the ischemic muscle microenvironment. Here, we combined the single-cell RNA sequencing and genetic lineage tracing technology and then provided exact single-cell atlases of normal and ischemic limb tissues in human and mouse, consequently found that bone marrow-derived macrophages with antigen-presenting function migrated to the ischemic site, while resident macrophages underwent apoptosis. The macrophage oncostatin M (OSM) regulatory pathway was specifically turned on by ischemia. Simultaneously, bone marrow CD34+-derived pro-regenerative fibroblasts were recruited to the ischemia niche, where they received macrophage-released OSM, and promoted angiopoietin-like protein (ANGPTL)-associated angiogenesis. These findings provided novel mechanisms on the cellular events and cell–cell communications during tissue ischemia and regeneration, and provided new evidence that CD34+ cells serve as fibroblast progenitors promoting tissue regeneration.

Project description:Background: The angiogenic response to ischemia restores perfusion so as to preserve tissue. A role for mesenchymal-to-endothelial transition in the angiogenic response is controversial. This study is to determine if resident fibroblasts contribute to angiogenesis. Methods: We utilized the murine model of hindlimb ischemia, and in vivo matrigel plug assay together with lineage tracing studies and single cell RNA-sequencing (scRNA-seq) to examine the transcriptional and functional changes in fibroblasts in response to ischemia. Results: Lineage tracing using Fsp1-Cre: R26R-EYFP mice revealed the emergence within the ischemic hindlimb of a small subset of YFP+ CD144+ CD11b- fibroblasts (E*cells) that expressed endothelial cell (EC) genes. Subcutaneous administration of matrigel in Fsp1-Cre: R26R-EYFP mice generated a plug that became vascularized within 5 days. Isolation of YFP+ CD11b- cells from the plug revealed a small subset of YFP+ CD144+ CD11b- E*cells which expressed EC genes. Pharmacological or genetic suppression of innate immune signaling reduced vascularity of the matrigel plug and abrogated the generation of these E*cells. These studies were repeated using human fibroblasts, with FACS analysis revealing that a small percentage of human fibroblasts that were induced to express EC markers in the matrigel plug assay. Pharmacological suppression or genetic knockout of inflammatory signaling abolished the generation of E*cells, impaired perfusion recovery and increased tissue injury after femoral artery ligation. To further characterize these E*cells, we performed scRNA-seq and revealed eight discrete clusters of cells expressing characteristic fibroblast genes, of which two clusters (C5 and C8) also expressed some EC genes. Ischemia of the hindlimb induced expansion of clusters C5 and C8. The C8 cells did not express CD144, nor did they form networks in Matrigel, but did generate angiogenic cytokines. The C5 fibroblasts most resembled E* cells in their expression of CD144 and their ability to form EC-like networks in Matrigel. Conclusion: Together, these studies indicate the presence of subsets of tissue fibroblasts which seem poised to contribute to the angiogenic response. The expansion of these subsets with ischemia is dependent upon activation of innate immune signaling, and contributes to recovery of perfusion and preservation of ischemic tissue.

Project description:to gain a better understanding on the genomic mechanisms involved in defective healing in diabetes, we characterized here the gene expression profile and gene-gene interaction network of cultured fibroblasts derived from chronic diabetic leg ulcers comparatively to fibroblast obtained from control donors. Comparative transcriptomic analysis of cultured fibroblasts derived from six diabetic leg ulcers and five control fibroblasts using DNA microarrays and bioinformatics tools for studying gene-gene interaction networks.

Project description:Research of human vocal fold (VF) biology is hampered by several factors. The sensitive microstructure of the VF mucosa is one of them and limits the in vivo research, as biopsies carry the unbearable risk of scarring. A laryngeal organotypic model consisting of VF epithelial cells and VF fibroblasts (VFF) might overcome some of the limitations. Whereas human VFF are available in several forms, availability of VF epithelial cells is scarce. Buccal mucosa might be a good source, as it is easily accessible, and biopsies heal without scarring. For this project we generated organotypic constructs consisting of immortalized human VF fibroblasts and primary human buccal epithelial cells. The constructs (n = 3) were compared to native laryngeal mucosa on a histological and proteomic level. The engineered constructs reassembled into a mucosa-like structure, after a cultivation period of 35 days. Immunohistochemical staining confirmed a multi-layered stratified epithelium, a collagen type IV positive barrier-like structure resembling the basal membrane, and an underlying layer containing VFF. Proteomic analysis revealed a total number of 1961 proteins. Of these, 83.8% were detected in both native VF and constructs, with only 53 proteins having significantly different abundance. 15.3% of detected proteins were identified in native VF mucosa only, most likely due to endothelial, immune and muscle cells within the VF samples, while 0.9% were found only in the constructs. Based on easily available cell sources, we could demonstrate that our organotypic laryngeal mucosa model shares many characteristics with native VF mucosa. It represents a stable and reproducible in vitro model and offers a wide range of possibilities ranging from the exploration of VF biology to the testing of interventions (e.g. drug testing).

Project description:Diabetes mellitus is one of the most chronic diseases, of which diabetic cardiomyopathy is the major cause of morbidity and involves in multiple processes such as inflammation, oxidative stress, fibrosis, extracellular collagen deposition, apoptosis, mitochondria dysfunction. However, the exact mechanisms of fibroblasts concerning type Ⅰ diabetes remain unclear. To further understand the functional roles of fibroblasts of STZ-induced diabetic mice, we lead the single cell RNA sequence. Cells were comprised of endothelial, fibroblast, cardiomyocyte, smooth muscle cells, macrophage and other type cells. Single cell sequence illustrates novel fibroblast sub-clusters and highlight the role of Lox. Real-time quantitative PCR, western blotting, immunofluorescence was used to verify the sequence data. We validate the dysfunctions of diabetic cardiomyopathy by echocardiogram. Our study supports novel insights into the pathogenesis of diabetic cardiomyopathy.

Project description:Vasculogenic Skin Reprogramming Requires TET-mediated Gene Demethylation in Fibroblasts for Rescuing Impaired Perfusion in Diabetes

Project description:Objective: To define the role of epigenetics, particularly DNA methylation in adaptive vascular growth in hyperlipidemic and type 2 diabetic mouse models of hind limb ischemia Methods: Unilateral hindlimb ischemia was induced by ligating femoral artery proximal to the bifurcation of superficial and deep femoral artery. DNA was isolated from ischemic muscles collected at day 7 after ischemia induction using DNeasy Tissue kit (Qiagen). 5 µg of genomic DNA was sheared into small fragments with a mean size of 150 bp by using a Covaris™ S2 sonicator System. Quality of the fragmentation was analyzed with Bioanalyzer. Fragmented DNA samples were used for preparation of DNA fragment libraries and sequenced on the SOLiD4 sequencing instrument on one flow cell for 50 bp reads. The sequencing reads were mapped to mus musculus genome build mm9. Data was analyzed by using Bioscope. The samples were normalized with the MEDIPS package in R/B Bioconductor. The analysis of CpG methylation was done primarily in the proximal promoter regions encompassing a region of –1kb upstream of the transcription start site (TSS) and +500 bp downstream of the TSS. Comparisons were performed between hyperlipidemic versus controls and diabetic versus controls to detect differentially methylated regions. R package Limma was used for performing the statistical testing between the groups. Results: When visualizing the whole normalized data the samples did not cluster according to the sample groups. Especially two samples from hyperlipidemic and diabetic ischemic muscles differed clearly from the rest of the samples. To detect the differentially methylated genes, stringent thresholds for p-values and fold change values were chosen to list a reasonable number of genes. Upon filtering, significant differences in the methylation patterns of the sample groups were observed. More importantly, when clustering only the filtered genes, the samples clustered clearly according to the sample groups giving evidence of condition-dependent behavior. Using a threshold of methylation fold change of >1.2 and p value <0.05, we identified 397 and 446 genes to be hypomethylated in hyperlipidemic and diabetic ischemic muscles respectively compared to controls. There were 46 genes commonly shared, but still having a unique pattern of hypomethylation in 371 and 394 genes in hyperlipidemic and diabetic ischemic muscles respectively compared to controls. Similarly, there were 371 and 394 genes hypermethylated in hyperlipidemic and diabetic ischemic respectively compared to controls. Interestingly, we found 264 genes to be commonly hypermethylated, whereas 107 and 130 genes were uniquely hypermethylated in hyperlipidemic and diabetic ischemic muscles respectively. Thus, proximal promoter methylation suggested a shared, yet distinct pattern of DNA methylation in ischemic muscles of hyperlipidemic and type 2 diabetic mice compared to controls. Out of 397 genes that were hypomethylated in hyperlipidemic ischemic muscle, 68 genes were shown to be upregulated in ‘proinflammatory M1 macrophages’ as shown by recent studies. Similarly, out of the 371 hypermethylated genes 93 genes were shown to be upregulated in ‘anti-inflammatory and proangiogenic M2 macrophages’ as described recently. Out of 446 hypomethylated genes in diabetic ischemic muscle, 65 genes were shown to be upregulated in ‘proinflammatory M1 macrophages’ as shown recently. Similarly, out of 394 hypermethylated genes 105 genes were specifically upregulated in ‘anti-inflammatory and proangiogenic M2 macrophages’ as shown recently. qRT-PCR analysis suggested an inverse relationship between proximal promoter hypermethylation and mRNA expression in a subset of M2 macrophage specific genes in hyperlipidemic and type 2 diabetic ischemic muscles compared to control ischemic muscles. Conclusions: Our results suggest a role of epigenetics particularly proximal promoter DNA methylation in macrophage polarization and their contribution to angiogenesis and tissue repair in hyperlipidemic and type 2 diabetic mouse models of hind limb ischemia. Epigenetics at the level of DNA methylation may act as a deciding factor in promoting a pro or anti-inflammatory phenotype of macrophages critical in cardiovascular diseases. Ischemic skeletal muscle DNA methylation sequencing of triplicate samples from C57BL/6J (WT) mice, hyperlipidemic mice (LDLR-/-ApoB100/100 , C57BL/6J background) and type 2 diabetic mice (IGF-II/LDLR-/-ApoB100/100 , C57BL/6J background) using SoliD4 sequencing platform

Project description:Comparative analysis of transcriptomes of skin fibroblasts in 17 Type 2 Diabetic individuals by RNA sequencing.