Project description:Our study comprehensively investigated the epigenetic features of cardiac F4/80+CD45+ macrophages at 3 and 7 days after P1 and P10 MI at infarct, border, and remote zones of mouse hearts (IZ, BZ, and RZ) through single cell H3K27ac ChIP-seq. we identified 9 subclusters and analyzed their potential functions, cluster-specific enhancer features, and enrichment of cell-type specific transcription factors. Surprisingly, we found intracluster epigenetic heterogeneity exists with biological functions. Moreover, we identified two MI-responsive lineages and targeted one inflammatory lineage exhibiting obvious pre-regenerative function.

Project description:Introduction: Cardiac ischemic reperfusion injury (IRI) is paradoxically instigated by re-establishing blood-flow to ischemic myocardium typically from a myocardial infarction (MI). Although revascularization following MI remains the standard of care, effective strategies remain limited to prevent or attenuate IRI. We hypothesized that epicardial placement of human placental amnion/chorion (HPAC) grafts will protect against IRI. Methods: Using a clinically relevant model of IRI, swine were subjected to 45 minutes percutaneous ischemia followed with (MI+HPAC, n=3) or without (MI only, n=3) HPAC. Cardiac function was assessed by echocardiography, and regional punch biopsies were collected 14 days post-operatively. A deep phenotyping approach was implemented by using histological interrogation and incorporating global proteomics and transcriptomics in non-ischemic, ischemic, and border zone biopsies. Results: Our results established HPAC limited the extent of cardiac injury by 50% (11.02.0% vs 22.03.0%, p=0.039) and preserved ejection fraction in HPAC-treated swine (46.8±2.7% vs 35.8±4.5%, p=0.014). We present comprehensive transcriptome and proteome profiles of infarct (IZ), border (BZ), and remote (RZ) zone punch biopsies from swine myocardium during the proliferative cardiac repair phase 14 days post-MI. Both HPAC-treated and untreated tissues showed regional dynamic responses, whereas only HPAC-treated IZ revealed active immune and extracellular matrix remodeling. Decreased endoplasmic reticulum (ER)-dependent protein secretion and increased anti-apoptotic and anti-inflammatory responses were measured in HPAC-treated biopsies. Discussion: We provide quantitative evidence HPAC reduced cardiac injury from MI in a preclinical swine model, establishing a potential new therapeutic strategy for IRI.

Project description:Sterile inflammation after myocardial infarction (MI) is classically credited to myeloid cells interacting with dead cell debris in the infarct zone (IZ). Here, we show that borderzone cardiomyocytes are the dominant initiators of a novel type I interferon (IFN) response in the infarct borderzone zone (BZ). Using spatial transcriptomics analysis of mice and humans, we find that MI induces colonies of interferon induced cells (IFNICs) expressing interferon stimulated genes (ISGs) decorating the BZ, where cardiomyocytes experience mechanical stress, nuclear rupture, and escape of chromosomal DNA. Cardiomyocyte-selective deletion of interferon regulatory factor 3 (Irf3) abrogated IFNIC colonies, whereas mice lacking Irf3 in fibroblasts, macrophages, neutrophils, or endothelial cells; Ccr2-deficient mice; or plasmacytoid dendritic cell-depleted mice did not. IFNs blunted the protective matricellular programs and contractile function of BZ fibroblasts, and increased vulnerability to pathologic remodeling. In mice that died after MI, IFNIC colonies were immediately adjacent to sites of ventricular rupture, while mice lacking IFNICs were protected from rupture and exhibited improved survival. Together, these results reveal a pathologic BZ niche characterized by a cardiomyocyte-initiated innate immune response. We suggest that selective inhibition of Irf3 activation in non-immune cells of the borderzone could limit ischemic cardiomyopathy while avoiding broad immunosuppression.

Project description:We applied an integrative single-cell genomics strategy with single nucleus RNA sequencing (snRNA-seq) and single nucleus Assay for Transposase-Accessible Chromatin sequencing (snATAC-seq) together with spatial transcriptomics from the same tissue mapping human cardiac cells in homeostasis and after myocardial infarction (MI) at unprecedented spatial and molecular resolution. We profiled in total 31 samples from 23 patients including four non-transplanted donor hearts as controls and samples from tissues with necrotic tissue areas (ischemic zone, IZ), border zone (BZ), and the non-affected left ventricular myocardium (remote zone, RZ) of patients with acute MI.

Project description:The growth plate is histomorphologically classified into four zones {resting zone (RZ), proliferating zone (PZ), maturing zone (MZ) and hypertrophic zone (HZ)}. Gene expression profile analyses of 4 zones were performed using microarrays.

Project description:Growth plate chondrocytes were isolated from the distal metacarpus of young dairy cattle (all under 10 mo of age), the chondrocytes were released from the extracellular matrix by digestion with Collagenase P for 4 hours, and the various zones of the growth plate were separated by density centrifugation. The least-dense Hypertrophic Zone (HZ) cells were compared to the most-dense Reserve Zone (RZ) cells. 6 pairs of HZ vs RZ were compared by microarray. Experiment Overall Design: Growth plate chondrocytes were isolated from the distal metacarpus of young dairy cattle (all under 10 mo of age), the chondrocytes were released from the extracellular matrix by digestion with Collagenase P for 4 hours, and the various zones of the growth plate were separated by density centrifugation. The least-dense Hypertrophic Zone (HZ) cells were compared to the most-dense Reserve Zone (RZ) cells. Six independent sample pairs of HZ vs RZ were compared by microarray.

Project description:Growth plate chondrocytes were isolated from the distal metacarpus of young dairy cattle (all under 10 mo of age), the chondrocytes were released from the extracellular matrix by digestion with Collagenase P for 4 hours, and the various zones of the growth plate were separated by density centrifugation. The least-dense Hypertrophic Zone (HZ) cells were compared to the most-dense Reserve Zone (RZ) cells. 6 pairs of HZ vs RZ were compared by microarray.

Project description:In the growth plate, the reserve and perichondral zones have been hypothesized to have similar functions, but their exact functions are poorly understood. Our hypothesis was that significant differential gene expression exists between perichondral and reserve chondrocytes that may differentiate the respective functions of these two zones. Normal Sprague-Dawley rat growth plate chondrocytes from the perichondral zone (PC), reserve zone (RZ), proliferative zone (PZ), and hypertrophic zone (HZ) were isolated by laser microdissection and then subjected to microarray analysis. In order to most comprehensively capture the unique features of the two zones, we analyzed both the most highly expressed genes and those that were most significantly different from the proliferative zone (PZ) as a single comparator. Keywords: cell specific expression profiles

Project description:In the growth plate, the reserve and perichondral zones have been hypothesized to have similar functions, but their exact functions are poorly understood. Our hypothesis was that significant differential gene expression exists between perichondral and reserve chondrocytes that may differentiate the respective functions of these two zones. Normal Sprague-Dawley rat growth plate chondrocytes from the perichondral zone (PC), reserve zone (RZ), proliferative zone (PZ), and hypertrophic zone (HZ) were isolated by laser microdissection and then subjected to microarray analysis. In order to most comprehensively capture the unique features of the two zones, we analyzed both the most highly expressed genes and those that were most significantly different from the proliferative zone (PZ) as a single comparator. Experiment Overall Design: 2 microarray replicates were obtained for each zone, using pooled quantities of RNA from 3 rats each at 42 and 46 days of age.

Project description:Nuclear-localized RNA binding proteins are involved in various aspects of RNA metabolism, which in turn modulates gene expression. However, the functions of nuclear-localized RNA binding proteins in plants are poorly understood. Here we report the functions of two proteins containing RNA recognition motifs, At RZ-1B and At RZ-1C, in Arabidopsis. At RZ-1B and At RZ-1C were localized to nuclear speckles and interacted with a spectrum of serine/arginine-rich (SR) proteins through their C-termini. At RZ-1C preferentially bound to purine-rich RNA sequences in vitro through its N-terminal RNA recognition motif. Disrupting the RNA-binding activity of At RZ-1C with SR proteins through over-expression of the C-terminus of At RZ-1C conferred defective phenotypes similar to those observed in At rz-1b/At rz-1c double mutants, including delayed seed germination, reduced stature, and serrated leaves. Loss of function of At RZ-1B and At RZ-1C was accompanied by defective splicing of many genes and global perturbation of gene expression. In addition, we found that At RZ-1C directly targeted FLC, promoting efficient splicing of FLC introns and likely also repressing FLC transcription. Our findings highlight the critical role of At RZ-1B/1C in regulating RNA splicing, gene expression, and many key aspects of plant development via interaction with proteins including SR proteins.