Migratory and anti-fibrotic programmes define the regenerative potential of human cardiac progenitors

Poch, Christine M; Foo, Kylie S.; Angelis, Maria Teresa De; Jennbacken, Karin; Santamaria, Gianluca; Bähr, Andrea; Reiter, Franziska; Hornaschewitz, Nadja; Zawada, Dorota; Bozoglu, Tarik; My, Ilaria; Meier, Anna B.; Dorn, Tatjana; Hege, Simon; Lehtinen, Markku; Tsoi, Yat Long; Hovdal, Daniel; Hyllner, Johan; Schwarz, Sascha; Sudhop, Stefanie; Jurisch, Victoria; Sini, Marcella; Fellows, Mick D.; Cummings, Matthew J.; Clarke, Jonathan; Baptista, R.; Eroğlu, Elif; Wolf, Eckhard; Klymiuk, Nikolai; Lü, Kun; Tomasi, Roland; Dendorfer, Andreas; Gaspari, Marco; Parrotta, Elvira Immacolata; Cuda, Giovanni; Krane, Markus; Sinnecker, Daniel; Hoppmann, Petra; Kupatt, Christian; Fritsche‐Danielson, Regina; Moretti, Alessandra; Chien, Kenneth R.; Laugwitz, Karl‐Ludwig

doi:10.1038/s41556-022-00899-8

Cited by 31 publications

(23 citation statements)

References 54 publications

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“…In addition to cell‐based therapy, there are cell‐free strategies, such as EVs and exosomes. Studies have illustrated that EVs derived from various stem cells harbour the ability of cardioprotection when delivered in murine models of MI 50,51 or HF 52,53 . Our findings confirm that CPPs exert reparative functions through CPPs‐Exo, as blocking exosome release abrogated the functional recovery achieved by delivery of CPPs into the ischemic area of the murine heart.…”

Section: Discussionsupporting

confidence: 79%

“…Studies have illustrated that EVs derived from various stem cells harbour the ability of cardioprotection when delivered in murine models of MI 50,51 or HF. 52,53 Our findings confirm that CPPs exert reparative functions through CPPs-Exo, as blocking exosome release abrogated the functional recovery achieved by delivery of CPPs into the ischemic area of the murine heart. Moreover, CPPs-Exo delivery at the early phase of MI recapitulates the beneficial effects of their parent cells in the treatment of MI.…”

Section: Discussionsupporting

confidence: 70%

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Cardiopulmonary progenitors facilitate cardiac repair via exosomal transfer of miR‐27b‐3p targeting the SIK1‐CREB1 axis

Xiao,

Xia,

Jiang

et al. 2024

Cell Proliferation

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Ischemic heart disease, especially myocardial infarction (MI), is one of the leading causes of death worldwide, and desperately needs effective treatments, such as cell therapy. Cardiopulmonary progenitors (CPPs) are stem cells for both heart and lung, but their repairing role in damaged heart is still unknown. Here, we obtained CPPs from E9.5 mouse embryos, maintained their stemness while expanding, and identified their characteristics by scRNA‐seq, flow cytometry, quantitative reverse transcription‐polymerase chain reaction, and differentiation assays. Moreover, we employed mouse MI model to investigate whether CPPs could repair the injured heart. Our data identified that CPPs exhibit hybrid fibroblastic, endothelial, and mesenchymal state, and they could differentiate into cell lineages within the cardiopulmonary system. Moreover, intramyocardial injection of CPPs improves cardiac function through CPPs exosomes (CPPs‐Exo) by promotion of cardiomyocytic proliferation and vascularization. To uncover the underlying mechanism, we used miRNA‐seq, bulk RNA‐seq, and bioinformatic approaches, and found the highly expressed miR‐27b‐3p in CPPs‐Exo and its target gene Sik1, which can influence the transcriptional activity of CREB1. Therefore, we postulate that CPPs facilitate cardiac repair partially through the SIK1‐CREB1 axis via exosomal miR‐27b‐3p. Our study offers a novel insight into the role of CPPs‐Exo in heart repair and highlights the potential of CPPs‐Exo as a promising therapeutic strategy for MI.

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Section: Discussionsupporting

confidence: 79%

Section: Discussionsupporting

confidence: 70%

Cardiopulmonary progenitors facilitate cardiac repair via exosomal transfer of miR‐27b‐3p targeting the SIK1‐CREB1 axis

Xiao,

Xia,

Jiang

et al. 2024

Cell Proliferation

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“…A previous in silico study showed that the risk of spontaneous hPSC-CM beats increases with higher hPSC-CM density, larger hPSC-CM clustering and injection proximal rather than distal to the infarct (Yu et al, 2019). In our study, we modelled the spatial distribution of hPSC-CM based on experimental observations from (Poch et al, 2022), rather than varying density, clustering and injection locations. Therefore, although the number of delivered cells relative to the scar size was maintained in our study, absolute cell number, density and clustering varied between the different scar geometries.…”

Section: Discussionmentioning

confidence: 99%

“…Existing adult ventricular cells (ToR-ORd model) were randomly replaced by the hPSC-CMs (Paci model), with probabilities depending on infarct versus border zone, transmurality and distance to the nearest delivery location (see supplementary Table S4 for further detail). Probabilities were calibrated using experimental insights from (Poch et al, 2022), where in non-human primate tissue slabs, more injected cells settled in the infarct core compared to the border zone. Informed by Poch et al’s in vivo porcine models, in our simulations, 28.4, 22.1 and 23.4 % (different due to scar morphology), of the core infarcted area was replaced by hPSC-CMs in the small, medium and large scar, respectively.…”

Section: Methodsmentioning

confidence: 99%

In SilicoEvaluation of Cell Therapy in Acute versus Chronic Infarction: Role of Automaticity, Heterogeneity and Purkinje in Human

Riebel,

Wang,

Martinez-Navarro

et al. 2023

Preprint

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Human-based modelling and simulation offer an ideal testbed for novel medical therapies to guide experimental and clinical studies. Myocardial infarction (MI) is a common cause of heart failure and mortality, for which novel therapies are urgently needed. Although cell therapy offers promise, electrophysiological heterogeneity raises pro-arrhythmic safety concerns, where underlying complex spatio-temporal dynamics cannot be investigated experimentally. After demonstrating credibility of the modelling and simulation framework, we investigate cell therapy in acute versus chronic MI, and the role of cell heterogeneity, scar size and the Purkinje system.Simulations agreed with experimental and clinical recordings from ionic to ECG dynamics in acute and chronic infarction. Following cell delivery, spontaneous beats were facilitated by heterogeneity in cell populations, chronic MI due to tissue depolarisation, and slow sinus rhythm. Subsequent re-entrant arrhythmias occurred, in some instances with Purkinje involvement, and their susceptibility was enhanced by impaired Purkinje-myocardium coupling, large scars, and acute infarction.We conclude that homogeneity in injected cell populations minimises their spontaneous beating, which is enhanced by chronic MI, whereas a healthy Purkinje-myocardium coupling is key to prevent subsequent re-entrant arrhythmias, particularly for large scars.

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“…There is evidence that progenitor cells may stimulate cardiac repair and regeneration by producing wide range of cytoprotective, anti-inflammatory and angiogenesis promoting factors leading to oxidative stress reduction, ventricle remodeling inhibition and recruitment of endogenous progenitor cells [8][9][10].…”

Section: Introductionmentioning

confidence: 99%

Single-photon emission computed tomography as a fundamental tool in evaluation of myocardial reparation and regeneration therapies

Tekieli¹,

Szot²,

Kwiecień³

et al. 2022

pwki

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Despite unquestionable progress in interventional and pharmacologic therapies of ischemic heart disease, the number of patients with chronic ischemic heart failure is increasing and the prognosis remains poor. Repair/restoration of functional myocardium through progenitor cell-mediated (PCs) healing and renovation of injured myocardium is one of the pivotal directions in biomedical research. PCs release numerous pro-angiogenic and anti-apoptotic factors. Moreover, they have self-renewal capability and may differentiate into specialized cells that include endothelial cells and cardiomyocytes. Uptake and homing of PCs in the zone(s) of ischaemic injury (i.e., their effective transplantation to the target zone) is an essential pre-requisite for any potential therapeutic effect; thus effective cell tracking is fundamental in pre-clinical and early clinical studies. Another crucial requirement in rigorous research is quantification of the infarct zone, including the amount of non-perfused and hypo-perfused myocardium. Quantitative and reproducible evaluation of global and regional myocardial contractility and left ventricular remodeling is particularly relevant in clinical studies. Using SPECT, our earlier work has addressed several critical questions in cardiac regenerative medicine including optimizing transcoronary cell delivery, determination of the zone(s) of myocardial cell uptake, and late functional improvement in relation to the magnitude of cell uptake. Here, we review the role of single-photon emission computed tomography (SPECT), a technique that offers high-sensitivity, quantitative cell tracking on top of its ability to evaluate myocardial perfusion and function on both cross-sectional and longitudinal bases. SPECT, with its direct relevance to routine clinical practice, is a fundamental tool in evaluation of myocardial reparation and regeneration therapies.

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Migratory and anti-fibrotic programmes define the regenerative potential of human cardiac progenitors

Cited by 31 publications

References 54 publications

Cardiopulmonary progenitors facilitate cardiac repair via exosomal transfer of miR‐27b‐3p targeting the SIK1‐CREB1 axis

Cardiopulmonary progenitors facilitate cardiac repair via exosomal transfer of miR‐27b‐3p targeting the SIK1‐CREB1 axis

In SilicoEvaluation of Cell Therapy in Acute versus Chronic Infarction: Role of Automaticity, Heterogeneity and Purkinje in Human

Single-photon emission computed tomography as a fundamental tool in evaluation of myocardial reparation and regeneration therapies

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