Fibrin, Bone Marrow Cells and Macrophages Interactively Modulate Cardiomyoblast Fate

Overview

Journal Biomedicines

Specialty Biomedical Engineering

Date 2022 Mar 25

PMID 35327330

Authors

Ines Borrego

Aurelien Frobert

Guillaume Ajalbert

Jeremy Valentin

Cyrielle Kaltenrieder

Benoit Fellay

Michael Stumpe

Stephane Cook

Joern Dengjel

Marie-Noelle Giraud

Affiliations

Soon will be listed here.

Abstract

Interactions between macrophages, cardiac cells and the extracellular matrix are crucial for cardiac repair following myocardial infarction (MI). We hypothesized that cell-based treatments might modulate these interactions. After validating that bone marrow cells (BMC) associated with fibrin lowered the infarct extent and improved cardiac function, we interrogated the influence of fibrin, as a biologically active scaffold, on the secretome of BMC and the impact of their association on macrophage fate and cardiomyoblast proliferation. In vitro, BMC were primed with fibrin (F-BMC). RT-PCR and proteomic analyses showed that fibrin profoundly influenced the gene expression and the secretome of BMCs. Consequently, the secretome of F-BMC increased the spreading of cardiomyoblasts and showed an alleviated immunomodulatory capacity. Indeed, the proliferation of anti-inflammatory macrophages was augmented, and the phenotype of pro-inflammatory switched as shown by downregulated , and and upregulated , CD163, and . Interestingly, the secretome of F-BMC educated-macrophages stimulated the incorporation of EdU in cardiomyoblasts. In conclusion, our study provides evidence that BMC/fibrin-based treatment improved cardiac structure and function following MI. In vitro proofs-of-concept reveal that the F-BMC secretome increases cardiac cell size and promotes an anti-inflammatory response. Thenceforward, the F-BMC educated macrophages sequentially stimulated cardiac cell proliferation.

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