Mesodermal iPSC–derived progenitor cells functionally regenerate cardiac and skeletal muscle
Mattia Quattrocelli, Melissa Swinnen, Giorgia Giacomazzi, Jordi Camps, Ines Barthélemy, Gabriele Ceccarelli, Ellen Caluwé, Hanne Grosemans, Lieven Thorrez, Gloria Pelizzo, Manja Muijtjens, Catherine M. Verfaillie, Stephane Blot, Stefan Janssens, Maurilio Sampaolesi
Mattia Quattrocelli, Melissa Swinnen, Giorgia Giacomazzi, Jordi Camps, Ines Barthélemy, Gabriele Ceccarelli, Ellen Caluwé, Hanne Grosemans, Lieven Thorrez, Gloria Pelizzo, Manja Muijtjens, Catherine M. Verfaillie, Stephane Blot, Stefan Janssens, Maurilio Sampaolesi
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Research Article Muscle biology

Mesodermal iPSC–derived progenitor cells functionally regenerate cardiac and skeletal muscle

Abstract

Conditions such as muscular dystrophies (MDs) that affect both cardiac and skeletal muscles would benefit from therapeutic strategies that enable regeneration of both of these striated muscle types. Protocols have been developed to promote induced pluripotent stem cells (iPSCs) to differentiate toward cardiac or skeletal muscle; however, there are currently no strategies to simultaneously target both muscle types. Tissues exhibit specific epigenetic alterations; therefore, source-related lineage biases have the potential to improve iPSC-driven multilineage differentiation. Here, we determined that differential myogenic propensity influences the commitment of isogenic iPSCs and a specifically isolated pool of mesodermal iPSC-derived progenitors (MiPs) toward the striated muscle lineages. Differential myogenic propensity did not influence pluripotency, but did selectively enhance chimerism of MiP-derived tissue in both fetal and adult skeletal muscle. When injected into dystrophic mice, MiPs engrafted and repaired both skeletal and cardiac muscle, reducing functional defects. Similarly, engraftment into dystrophic mice of canine MiPs from dystrophic dogs that had undergone TALEN-mediated correction of the MD-associated mutation also resulted in functional striatal muscle regeneration. Moreover, human MiPs exhibited the same capacity for the dual differentiation observed in murine and canine MiPs. The findings of this study suggest that MiPs should be further explored for combined therapy of cardiac and skeletal muscles.

Authors

Mattia Quattrocelli, Melissa Swinnen, Giorgia Giacomazzi, Jordi Camps, Ines Barthélemy, Gabriele Ceccarelli, Ellen Caluwé, Hanne Grosemans, Lieven Thorrez, Gloria Pelizzo, Manja Muijtjens, Catherine M. Verfaillie, Stephane Blot, Stefan Janssens, Maurilio Sampaolesi

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Figure 4

Differential myogenic propensity correlates with specific epigenetic signatures.

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Differential myogenic propensity correlates with specific epigenetic sig...
(A) At both iPSC and MiP stages, we compared the quantitative epigenetic data (methylation percentage by 1-way ANOVA and histone mark enrichment by 2-way ANOVA) of f- and MAB-derived cells in specific loci using a hierarchical system of three queries. Query 1 (Q1) addressed the difference between f- and MAB-derived cells within the same stage. When Q1 = *, we addressed the difference between each cell population and the related parental cells within the same progeny (Q2a, f progeny; Q2b, MAB progeny). When Q2a = Q2b = NS, the bias was considered inherited (§); when Q2a = Q2B = *, the bias was considered remodeled ($); finally, in cases of nonunivocal results (Q2a ≠ Q2b), the bias was considered stochastic (#). This statistical categorization was applied to both bisulphite sequencing (DNA methylation; data expressed as a percentage of methylated CpGs) and ChIP-qPCR data (H3K marks; data expressed as a percentage of input) of CpG islands of target genes. (B) Following this statistical model, the pluripotency marker nanog showed stage-specific changes in epigenetic cues, with no progeny-related bias (Q1 = NS). (C) The mesodermal marker brachyury showed inherited, progeny-related bias in methylation (§), but remodeled biases in histone marks ($). MAB-iPSCs and MAB-MiPs showed more permissive/activating epigenetic cues (lower methylation, higher levels of H3K4me2 and H3K27ac). (D) The skeletal myogenesis marker Pax7 presented inherited biases in both methylation and histone marks at both iPSC (§) and MiP (§) stages. MAB-derived cells showed a durable bias in lower methylation and permissive/activating histone marks. (E) Conversely, the cardiac myogenesis marker Tbx5 showed stage-specific shifts in methylation and histone marks, with no significant progeny-related bias (Q1 = NS). Both MiP types showed low methylation levels and enrichment in H3K27ac. n = 3/cells pool. *P < 0.05, 1-way ANOVA with Bonferroni’s multiple comparisons test for DNA methylation analysis; 2-way ANOVA with Bonferroni’s multiple comparisons test for histone mark analysis. All analyses included data from isogenic clones from 3 syngeneic individuals. fibrobl, fibroblasts; mCpGs, methylated CpGs.