C-kit+VEGFR-2+ Mesenchymal Stem Cells Differentiate into Cardiovascular Cells and Repair Infarcted Myocardium after Transplantation

Background: Resent preclinical studies and clinical trails prove that transplantation of mesenchymal stem cells (MSCs) is a promised therapy for ischemic diseases. However, the properties of c-kit+ cells in MSCs remain unclear. We investigated the differential potential of c-kit+VEGFR-2+ MSCs and evaluated their effects on repairing the infarcted myocardium after transplantation. Methods: c-kit+VEGFR-2+ MSCs were isolated from rat bone marrow. Gene expression profile of the cells was examined with RNA-sequencing. Differential potential of the cells was determined after induction with VEGF, TGF-β and BMP-2 for 2 weeks. Improvement of cardiac function and repair of the infarcted myocardium were assessed at 4 weeks after transplantation of the cells preconditioned with hypoxia and serum deprivation. Results: Gene expression profile revealed that the upregulated genes are enrichment of genes related to immune process and cell differentiation. The cells represented a potential of differentiation towards endothelial cell, smooth muscle cells and cardiamyocytes. In hypoxic condition, secretion of VEGF, SCF and SDF-1α from the cells was increased. VEGF and SCF promoted proliferation and migration of the cells. VEGF could induce the cells to incorporate to the microvessels. After transplantation of the preconditioned cells into the infarcted myocardium, cardiac function was improved, scar size of the infarcted myocardium was decreased, and angiogensis and myocardium repair were enhanced significantly. With preconditioning and delivery by fibrin gel, survival of the cells in the ischemic tissue was augmented. Conclusion: These results suggest that c-kit+VEGFR-2+ MSCs have a potential of differentiation towards cardiovascular cells. SCF/c-kit and VEGF/VEGFR-2 singnalling pathways regulate proliferation, migration and differentiation of the cells. Transplantation of c-kit+VEGFR-2+ MSCs may enhance repair of the infarcted myocardium effectively.

Regulatory Mechanism of LINC00152 on Aggravating Heart Failure through Triggering Fibrosis in an Infarcted Myocardium

Objective. To elucidate the role of LINC00152 in the progression of heart failure following myocardial infarction. Patients and Methods. Serum levels of LINC00152 in acute myocardial infarction (AMI) patients were detected by quantitative real-time polymerase chain reaction (qRT-PCR). Receiver operating characteristic (ROC) curves were depicted for assessing the diagnostic value of LINC00152 in AMI. Subsequently, an in vivo AMI model was generated in mice. LINC00152 level in a mouse infarcted myocardium was detected. Echocardiogram was conducted to evaluate the influence of LINC00152 on cardiac function in AMI mice. Primary cardiac fibroblasts were isolated from neonatal mice. After knockdown of LINC00152, proliferative and migratory changes in primary cardiac fibroblasts were assessed by cell counting kit-8 (CCK-8) and transwell assay, respectively. The regulatory effect of LINC00152 on Smad7 level was determined by qRT-PCR. Finally, the involvement of Smad7 in LINC00152-regulated proliferative and migratory abilities in primary cardiac fibroblasts was explored by rescue experiments. Results. Serum level of LINC00152 was elevated in AMI patients. ROC curves demonstrated the diagnostic potential of LINC00152 in AMI (95% CI: 0.806-0.940, p = 0.034 ). In myocardial tissues collected from AMI mice, LINC00152 level was higher than those collected from mice of the sham group. LVEF and FS markedly decreased in AMI mice overexpressing LINC00152 on the 4th week of AMI modeling. After knockdown of LINC00152 in primary cardiac fibroblasts, proliferative and migratory abilities were declined, which were abolished by Smad7 intervention. Conclusions. By downregulating Smad7, LINC00152 aggravates heart failure following AMI via promoting the proliferative and migratory abilities in cardiac fibroblasts.

Abstract 120: Pericytes Contribute To Myofibroblast Expansion And Vascular Maturation In The Infarcted Heart

Infarct healing is dependent on recruitment of inflammatory leukocytes and subsequent activation of myofibroblasts (MF) and neovessel formation, ultimately resulting in formation of a highly vascularized collagen-enriched scar. Though the heart has an abundant population of periendothelial pericytes, its role in wound healing upon myocardial infarction (MI) has not been studied. We hypothesized that in the infarcted myocardium, pericytes may become activated, contributing to inflammatory, fibrotic and angiogenic responses. We used pericyte/fibroblast reporter mice (NG2 DsRed ;PDGFRα GFP ), lineage tracing studies and in vitro approaches to study the fate and role of pericytes in the infarcted myocardium. In normal hearts, NG2+/PDGFRα- pericytes and PDGFRα+/NG2- fibroblasts had distinct transcriptomic profiles. Pericytes expressed mural genes like Acta2 , Pdgfrb and low amounts of extracellular matrix (ECM) genes, whereas fibroblasts synthesized collagens, Timp2/3 and matricellular genes. 7 days post-MI, expansion of the NG2+ population in the infarct zone was associated with emergence of non-mural NG2+/αSMA+ cells with MF characteristics. FACS-sorted NG2+/PDGFRα- cells from 7-day infarcts expressed higher levels of collagens when compared to NG2+/PDGFRα- cells from normal hearts. Infarct pericytes had high integrin and MMP14 expression, reflecting an activated migratory phenotype. Lineage tracing using NG2CreER TM ;Rosa tdTomato ;PDGFRα GFP mice showed that 5.7%±1.04 of PDGFRα+ fibroblasts and 10.49%±2.73 of infarct MFs were derived from NG2+ lineage. Pericyte-derived fibroblasts exhibited higher ECM gene synthesis, in comparison to fibroblasts from non-pericyte origin, while pericyte-derived mural cells showed accentuated inflammatory cytokine gene expression. Immunostaining showed pericytes actively contribute to vascular maturation, forming a mural cell coat enwrapping infarct neovessels. In vitro, TGFβ induced integrins, collagens and MMPs in human pericytes, similar to the changes observed in infarct pericytes. Taken together, our evidences show that after MI, pericytes become activated and contribute to repair by undergoing conversion to a subset of myofibroblasts and by coating infarct neovessels.

SDF-1 Molecularly Imprinted Biomimetic Scaffold as a Potential Strategy to Repair the Infarcted Myocardium

Background: In situ cardiac tissue engineering aims to heal the infarcted myocardium by guiding tissue regeneration within the patient body. A key step in this approach is the design of a bioactive scaffold, able to stimulate tissue repair at the site of damage. In the development of bioactive scaffolds, molecular imprinting nanotechnology has been recently proposed as a new functionalization strategy. Objectives: In this work, Molecularly Imprinted Particles (MIP) with recognition properties towards the stromal-derived factor-1 (SDF-1) were synthesized, characterized and used for the functionalization of a biomimetic scaffold. MIP are expected to favor the enrichment of the SDF-1 bioactive molecule within the scaffold, thereby promoting myocardial regeneration. Methods: MIP were obtained by precipitation polymerization, using the SDF-1 molecule as a template. Alginate/gelatin/elastin sponges were fabricated by freeze-drying and functionalized by MIP deposition. Morphological, physicochemical and functional analyses were performed both on MIP and on MIP-modified scaffolds. A preliminary biological in vitro investigation was also carried out using rat cardiac progenitor cells (rCPCs). Results: Imprinted nanoparticles with an average diameter between 0.6 and 0.9 µm were obtained. Infrared analysis of MIP confirmed the expected chemical structure. Recognition and selectivity tests showed that MIP were able to selectively recognize and rebind the template, even after their deposition on the scaffold. In vitro biological tests showed that cell adhesion to the scaffold was promoted by MIP functionalization. Conclusion: Results obtained in the present study suggest that biomimetic alginate/gelatin/elastin sponges, functionalized by MIP with recognition properties towards SDF-1, could be successfully used for tissue engineering approaches to repair the infarcted heart.

Characterization of the Electrophysiologic Remodeling of Patients With Ischemic Cardiomyopathy by Clinical Measurements and Computer Simulations Coupled With Machine Learning

RationalePatients with ischemic cardiomyopathy (ICMP) are at high risk for malignant arrhythmias, largely due to electrophysiological remodeling of the non-infarcted myocardium. The electrophysiological properties of the non-infarcted myocardium of patients with ICMP remain largely unknown.ObjectivesTo assess the pro-arrhythmic behavior of non-infarcted myocardium in ICMP patients and couple computational simulations with machine learning to establish a methodology for the development of disease-specific action potential models based on clinically measured action potential duration restitution (APDR) data.Methods and ResultsWe enrolled 22 patients undergoing left-sided ablation (10 ICMP) and compared APDRs between ICMP and structurally normal left ventricles (SNLVs). APDRs were clinically assessed with a decremental pacing protocol. Using genetic algorithms (GAs), we constructed populations of action potential models that incorporate the cohort-specific APDRs. The variability in the populations of ICMP and SNLV models was captured by clustering models based on their similarity using unsupervised machine learning. The pro-arrhythmic potential of ICMP and SNLV models was assessed in cell- and tissue-level simulations. Clinical measurements established that ICMP patients have a steeper APDR slope compared to SNLV (by 38%, p < 0.01). In cell-level simulations, APD alternans were induced in ICMP models at a longer cycle length compared to SNLV models (385–400 vs 355 ms). In tissue-level simulations, ICMP models were more susceptible for sustained functional re-entry compared to SNLV models.ConclusionMyocardial remodeling in ICMP patients is manifested as a steeper APDR compared to SNLV, which underlies the greater arrhythmogenic propensity in these patients, as demonstrated by cell- and tissue-level simulations using action potential models developed by GAs from clinical measurements. The methodology presented here captures the uncertainty inherent to GAs model development and provides a blueprint for use in future studies aimed at evaluating electrophysiological remodeling resulting from other cardiac diseases.

Assessment of stunned and viable myocardium using manganese-enhanced MRI

ObjectiveIn a proof-of-concept study, to quantify myocardial viability in patients with acute myocardial infarction using manganese-enhanced MRI (MEMRI), a measure of intracellular calcium handling.MethodsHealthy volunteers (n=20) and patients with ST-elevation myocardial infarction (n=20) underwent late gadolinium enhancement (LGE) using gadobutrol and MEMRI using manganese dipyridoxyl diphosphate. Patients were scanned ≤7 days after reperfusion and rescanned after 3 months. Differential manganese uptake was described using a two-compartment model.ResultsAfter manganese administration, healthy control and remote non-infarcted myocardium showed a sustained 25% reduction in T1 values (mean reductions, 288±34 and 281±12 ms). Infarcted myocardium demonstrated less T1 shortening than healthy control or remote myocardium (1157±74 vs 859±36 and 835±28 ms; both p<0.0001) with intermediate T1 values (1007±31 ms) in peri-infarct regions. Compared with LGE, MEMRI was more sensitive in detecting dysfunctional myocardium (dysfunctional fraction 40.5±11.9 vs 34.9%±13.9%; p=0.02) and tracked more closely with abnormal wall motion (r2=0.72 vs 0.55; p<0.0001). Kinetic modelling showed reduced myocardial manganese influx between remote, peri-infarct and infarct regions, enabling absolute discrimination of infarcted myocardium. After 3 months, manganese uptake increased in peri-infarct regions (16.5±3.5 vs 22.8±3.5 mL/100 g/min, p<0.0001), but not the remote (23.3±2.8 vs 23.0±3.2 mL/100 g/min, p=0.8) or infarcted (11.5±3.7 vs 14.0±1.2 mL/100 g/min, p>0.1) myocardium.ConclusionsThrough visualisation of intracellular calcium handling, MEMRI accurately differentiates infarcted, stunned and viable myocardium, and correlates with myocardial dysfunction better than LGE. MEMRI holds major promise in directly assessing myocardial viability, function and calcium handling across a range of cardiac diseases.Trial registration numbersNCT03607669; EudraCT number 2016-003782-25.