Project description:Background. Accumulation of extracellular matrix in the myocardium attenuates cardiac contractile function, and predisposes to arrhythmias and sudden cardiac death. Connective tissue growth factor (CTGF) is a matricellular protein that has been shown to promote development of cardiac fibrosis. Objectives. To investigate for the potential of CTGF monoclonal antibody (CTGF mAb) in protecting from development of cardiac fibrosis following myocardial infarction (MI), and to evaluate its effect during infarct repair and acute cardiac ischemia-reperfusion (I/R) injury. Methods. Mice were subjected to MI or to I/R injury and treated with either control IgG or CTGF mAb. Cultured human cardiac fibroblasts were used to investigate the signalling mechanisms modulated by CTGF mAb. Results. Treatment with CTGF mAb for four days from day three after MI improved survival, attenuated infarct expansion, and resulted in better preserved left ventricular (LV) systolic function. CTGF mAb therapy for six weeks from day seven after MI reduced the MI-induced increase in cardiomyocyte size, heart weight to body weight ratio and remote LV fibrosis. RNA sequencing analysis of LV samples showed that CTGF mAb induced expression of cardiac repair/developmental genes and normalized the MI-induced increase in expression of inflammatory/profibrotic genes. CTGF mAb induced c-Jun N-terminal kinase (JNK) phosphorylation in vivo and in vitro, and inhibition of JNK abrogated the reduced collagen production in CTGF mAb treated fibroblasts. Conclusions. Treatment with CTGF mAb induces expression of cardiac repair/developmental genes and inhibits expression of inflammatory/pro-fibrotic genes in MI hearts providing benefit during post-MI cardiac repair and reducing post-MI cardiac fibrosis.

Project description:The Murphy Roth Large (MRL) mouse, a strain capable of regenerating right ventricular myocardium, has a high post-myocardial infarction (MI) survival rate compared with C57BL6/J (C57) mice. The biological processes responsible for this survival advantage are unknown. We compared acute post-MI gene expression in C57 and MRL hearts using microarrays and identified promising candidate biological processes underlying increased survival in the MRL. Hearts from both strains were excised at different time points before or after MI for RNA extraction and hybridization to MOE430A arrays. Baseline hearts were excised from healthy mice that had not undergone the MI procedure (day 0). Infarct tissue in this case means tissue taken from the anterior-apical region that would be the infarct region in a post-MI heart. Non-infarct covers the remainder of the LV. Post-MI hearts were excised either 1 or 5 days after MI. We had successful hybridizations for 3 replicates each of C57 day 0 infarct and non-infarct tissue (6 arrays), 4 MRL day 0 infarct and non-infarct tissue (8 arrays), 4 C57 day 1 infarct and non-infarct tissue (8 arrays), 4 MRL day 1 infarct and non-infarct tissue (8 arrays), 4 C57 day 5 infarct and non-infarct tissue (8 arrays), and 4 MRL day 5 infarct and non-infarct tissue (8 arrays).

Project description:Epigenetic regulation of histone H3K27 methylation has recently emerged as a key step during alternative M2-like macrophage (M2) polarization, essential for cardiac repair after Myocardial Infarction (MI). We hypothesized that EZH2, responsible for H3K27 methylation, could act as an epigenetic checkpoint regulator during this process. We demonstrate for the first time inactivation of EZH2 activity, linked to ectopic cytoplasmic localization of the epigenetic enzyme, during monocyte differentiation in vitro as well as in M2 macrophages in vivo during post-MI cardiac inflammation. Moreover, we show that pharmacological EZH2 inhibition, with GSK-343, resolves H3K27 methylation at the promoter of bivalent genes, thus enhancing their expression to promote human monocyte repair functions. In line with this protective effect, GSK-343 treatment accelerated cardiac inflammatory resolution preventing infarct expansion and subsequent cardiac dysfunction after MI in vivo. In conclusion, our study reveals that epigenetic modulation of cardiac-infiltrating immune cells may hold promise to limit adverse cardiac remodeling after MI.

Project description:Closed-chest reperfused MI was induced in pigs by 90-min occlusion, followed by reperfusion of the mid LAD (day 0) and by cardiac MRI with late enhancement (LE) at day 3. At day 30 the animals received either porcine APOSEC (n=8) or placebo medium (n=8) in a randomized manner, injected into the border zone of MI using 3D NOGA percutaneous intramyocardial guidance. At day 60, control cardiac MRI with LE and measurements of myocardial viability via diagnostic NOGA were performed. Gene expression profiling of the infarct core, border zone and normal myocardium was performed using microarray analysis, confirmed by quantitative real-time PCR. Percutaneous endomyocardial injections of APOSEC led to a significant (p<0.05) decrease in infarct size and in improvement of cardiac index and myocardial viability compared to medium treatment. Trend towards higher LV ejection fraction was observed in APOSEC vs. the Medium placebo group (45.4M-BM-15.9% vs 37.4M-BM-18.9%, p=0.052). Transcriptome analysis revealed significant downregulation of caspase-1 and other inflammatory genes in the APOSEC-affected areas. PCR showed higher expression of myogenic factor, Mefc2 (p<0.05) gene with downregulated caspase-3 (p<0.05) in the APOSEC-pigs. We have investigated the effects of catheter-based endomyocardial injections of APOSEC (secretome of apoptotic peripheral white blood cells) on porcine chronic post-infarction (MI) left ventricular (LV) dysfunction and gene expression profile. Pigs randomized to receive eithersecretome (n=8) or medium (placebo control, n=8)

Project description:Myocardial infarction (MI) results from occlusion of blood supply to the heart muscle causing death of cardiac muscle cells. Following myocardial infarction (MI), scar formation acts to mechanically stabilise the injured heart to prevent rupture and death. While fibroblasts and macrophages are implicated in post-MI scar formation and maturation, their exact contributions to this process are poorly characterised, especially in the long-term (i.e., beyond 1-week post-MI). Here, we employ state-of-the-art spatially-targetted optical micro-proteomics (STOMP) to isolate proteomes of tissue fractions enriched for fibroblasts (sma+) and macrophages (cd68+) over a 6-week post-MI timecourse and compare them to whole-scar proteome. We illustrate dynamic, specific changes in sma- and cd68-enriched fraction protein composition over 1-6 weeks post-MI with some of these changes reflected in whole-infarct preparations. These results link specific cell populations to specific protein changes in whole infarct.

Project description:The left anterior descending coronary artery permanent ligation model of myocardial infarction was used to study the time of day differences in genetic responses post-MI between sleep-time MI, wake-time MI, wake-sham and sleep-sham mouse hearts. The micorarray approach allows the investigation of gene expression changes of all genes in sleep-time MI vs. wake-time MI vs. sham hearts.

Project description:Objectives: To investigate the role of ALKBH5 in fibroblasts during post-myocardial infarction (MI) repair. Background: N6-methyladenosine (m6A) mRNA modification has been shown to play an important role in cardiovascular diseases. The RNA demethylase, AlkB homolog 5 (ALKBH5), is an m6A "eraser" that is responsible for decreased m6A methylation. However, its role in cardiac fibroblasts during the post-MI healing process remains elusive. Methods: MI was mimicked by permanent left anterior descending artery ligation in global ALKBH5-knockout, ALKBH5-knockin, and fibroblast-specific ALKBH5-knockout mice to study the function of ALKBH5 during post-MI collagen repair. Methylated RNA immunoprecipitation sequencing was performed to explore potential ALKBH5 targets. Results: Dramatic alterations in ALKBH5 expression were observed during the early stage post-MI and in hypoxic fibroblasts. Global ALKBH5 knockin reduced infarct size and improved cardiac function after MI. The global and fibroblast-specific ALKBH5-knockout mice both exhibited low survival rates along with poor collagen repair, impaired cardiac function, and cardiac rupture. Both in vivo and in vitro ALKBH5 loss led to impaired fibroblast activation and decreased collagen deposition. Additionally, hypoxia, but not TGF-β1 or Ang II, upregulated ALKBH5 expression in myofibroblasts in a HIF-1α-dependent transcriptional manner. Mechanistically, ALKBH5 promoted the stability of ErbB4 mRNA and the degradation of ST14 mRNA via m6A demethylation. Fibroblast-specific ErbB4 overexpression ameliorated the impaired fibroblast-to-myofibroblast transformation and poor post-MI repair due to ALKBH5 knockout. Conclusions: Fibroblast ALKBH5 positively regulates post-MI healing via post-transcriptional modification and stabilization of ErbB4 mRNA in an m6A-dependent manner. Targeting ALKBH5/ERBB4 may be a potential therapeutic option for post-MI cardiac rupture.

Project description:RATIONALE: Myocardial infarction (MI) triggers a dynamic microRNA response with the potential of yielding therapeutic targets. OBJECTIVE: We aimed to identify novel aberrantly expressed cardiac microRNAs post-MI with potential roles in adverse remodeling in a rat model, and to provide post-ischemic therapeutic inhibition of a candidate pathological microRNA in vivo. METHODS AND RESULTS: Following microRNA array profiling in rat hearts 2 and 14days post-MI, we identified a time-dependent up-regulation of miR-31 compared to sham-operated rats. A progressive increase of miR-31 (up to 91.4±11.3 fold) was detected in the infarcted myocardium by quantitative real-time PCR. Following target prediction analysis, reporter gene assays confirmed that miR-31 targets the 3´UTR of cardiac troponin-T (Tnnt2), E2F transcription factor 6 (E2f6), mineralocorticoid receptor (Nr3c2) and metalloproteinase inhibitor 4 (Timp4) mRNAs. In vitro, hypoxia and oxidative stress up-regulated miR-31 and suppressed target genes in cardiac cell cultures, whereas LNA-based oligonucleotide inhibition of miR-31 (miR-31i) reversed its repressive effect on target mRNAs. Therapeutic post-ischemic administration of miR-31i in rats silenced cardiac miR-31 and enhanced expression of target genes, while preserving cardiac structure and function at 2 and 4weeks post-MI. Left ventricular ejection fraction (EF) improved by 10% (from day 2 to 30 post-MI) in miR-31i-treated rats, whereas controls receiving scrambled LNA inhibitor or placebo incurred a 17% deterioration in EF. miR-31i decreased end-diastolic pressure and infarct size; attenuated interstitial fibrosis in the remote myocardium and enhanced cardiac output. CONCLUSION: miR-31 induction after MI is deleterious to cardiac function while its therapeutic inhibition in vivo ameliorates cardiac dysfunction and prevents the development of post-ischemic adverse remodeling.

Project description:infarct size and subsequent deterioration in function. The identification of factors that enhance cardiac repair by the restoration of the vascular network is, therefore, of great significance. Here, we show that the transcription factor Zinc finger E-box-binding homeobox 2 (ZEB2) is increased in stressed cardiomyocytes and induces a cardioprotective cross-talk between cardiomyocytes and endothelial cells to enhance angiogenesis after ischemia. Single-cell sequencing indicates ZEB2 to be enriched in injured cardiomyocytes. Cardiomyocyte-specific deletion of ZEB2 results in impaired cardiac contractility and infarct healing post-myocardial infarction (post-MI), while cardiomyocyte-specific ZEB2 overexpression improves cardiomyocyte survival and cardiac function. We identified Thymosin 4 (TMSB4) and Prothymosin (PTMA) as main paracrine factors released from cardiomyocytes to stimulate angiogenesis by enhancing endothelial cell migration, and whose regulation is validated in our in vivo models. Therapeutic delivery of ZEB2 to cardiomyocytes in the infarcted heart induces the expression of TMSB4 and PTMA, which enhances angiogenesis and prevents cardiac dysfunction. These findings reveal ZEB2 as a beneficial factor during ischemic injury, which may hold promise for the identification of new therapies.

Project description:Background—Mesenchymal stem cells (MSCs) have shown therapeutic potency for treating cardiovascular diseases, but their therapeutic efficacy shows significant heterogeneity depending on their tissue of origin. We herein sought to identify the optimal source of MSCs for cardiovascular disease therapy. Methods—Heart- and bone marrow (BM)-derived GFP+ cells positive for the MSCs marker, Nestin, were flow cytometrically sorted from 7-day-postnatal Nestin-GFP transgenic mice. To study their biological characteristics in vitro, we characterized their self-renewal capacity, multi-lineage differentiation ability, and surface markers. To investigate their therapeutic potential in vivo, we intramyocardially injected Nestin+ cells (3×105) into the infarct border zone of mice subjected to acute myocardial infarction (MI), and performed echocardiography and Masson’s-Trichrome staining at 1 and 3 weeks post-MI. We characterized gene profiles with RNA-sequencing analysis, and analyzed the putative reparative mechanism, that of Periostin-mediated M2 macrophages polarization, by immunofluorescence staining, qPCR, ELISA, and flow cytometry in vivo and in vitro. Results—In vitro, the heart- and BM-derived Nestin+ cells (Nes+cMSCs and Nes+bmMSCs, respectively) were found to possess self-renewal ability, show similar tri-lineage differentiation potentials, and express some MSCs-related surface markers. Importantly, Nes+cMSCs significantly improved cardiac function, attenuated left ventricular (LV) remodeling, and decreased infarct size in the mouse MI model, compared with Nes+bmMSCs- or saline-treated MI controls. Nes+cMSC treatment notably reduced the total number of CD68+ pan-macrophages while inducing the polarization of macrophages toward an anti-inflammatory M2 phenotype in ischemic myocardium, compared with the saline-treated MI control. Periostin, which was highly expressed in Nes+cMSCs, could promote the polarization of M2-subtype macrophages in vitro and in vivo. Finally, Periostin knockdown remarkably reduced the therapeutic effects of Nes+cMSCs, inhibiting the survival and LV remodeling of MI model mice and significantly decreasing the number of M2 macrophages at lesion sites. Conclusions—Nestin+ cMSCs have greater efficacy than Nestin+ bmMSCs for cardiac repair following acute MI, using a reparative mechanism that acts at least partly through Periostin-mediated M2 macrophage polarization.