CMPCs differentiated into the same cell types in situ as can be obtained in vitro. This excludes the need for in vitro pre-differentiation, making CMPCs a promising source for (autologous) cell-based therapy.
Understanding early differentiation events leading to cardiogenesis is crucial for controlling fate of human pluripotent stem cells and developing protocols that yield sufficient cell numbers for use in regenerative medicine and drug screening. Here, we develop a new tool to visualize patterning of early cardiac mesoderm and cardiomyocyte development in vitro by generating a dual MESP1 mCherry/w -NKX2-5 eGFP/w reporter line in human embryonic stem cells (hESCs) and using it to examine signals that lead to formation of cardiac progenitors and subsequent differentiation. MESP1 is a pivotal transcription factor for precardiac mesoderm in the embryo, from which the majority of cardiovascular cells arise. Transcription factor NKX2-5 is expressed upon cardiac crescent formation. Induction of cardiac differentiation in this reporter line resulted in transient expression of MESP1-mCherry, followed by continuous expression of NKX2-5-eGFP. MESP1-mCherry cells showed increased expression of mesodermal and epithelial-mesenchymal-transition markers confirming their mesodermal identity. Whole-genome microarray profiling and fluorescence-activated cell sorting analysis of MESP1-mCherry cells showed enrichment for mesodermal progenitor cell surface markers PDGFR-a, CD13, and ROR-2. No enrichment was found for the previously described KDR1PDGFR-a1 progenitors. MESP1-mCherry derivatives contained an enriched percentage of NKX2-5-eGFP and Troponin T expressing cells, indicating preferential cardiac differentiation; this was enhanced by inhibition of the Wnt-pathway. Furthermore, MESP1-mCherry derivatives harbored smooth muscle cells and endothelial cells, demonstrating their cardiac and vascular differentiation potential under appropriate conditions. The MESP1-NKX2-5 hESC reporter line allows us to identify molecular cues crucial for specification and expansion of human cardiac mesoderm and early progenitors and their differentiation to specific cardiovascular derivatives. STEM CELLS 2015;33:56-67
Transplantation of human embryonic stem cell-derived cardiomyocytes (hESC-CM) for cardiac regeneration is hampered by the formation of fibrotic tissue around the grafts, preventing electrophysiological coupling. Investigating this process, we found that: (1) beating hESC-CM in vitro are embedded in collagens, laminin and fibronectin, which they bind via appropriate integrins; (2) after transplantation into the mouse heart, hESC-CM continue to secrete collagen IV, XVIII and fibronectin; (3) integrin expression on hESC-CM largely matches the matrix type they encounter or secrete in vivo; (4) co-transplantation of hESC-derived endothelial cells and/or cardiac progenitors with hESC-CM results in the formation of functional capillaries; and (5) transplanted hESC-CM survive and mature in vivo for at least 24 weeks. These results form the basis of future developments aiming to reduce the adverse fibrotic reaction that currently complicates cell-based therapies for cardiac disease, and to provide an additional clue towards successful engraftment of cardiomyocytes by co-transplanting endothelial cells.Electronic supplementary materialThe online version of this article (doi:10.1007/s00018-009-0179-z) contains supplementary material, which is available to authorized users.
Transplantation of human embryonic stem cell-derived cardiomyocytes (hESC-CM) has been shown to improve the function of the rodent heart 1 month after myocardial infarction (MI). However, the mechanistic basis and optimal delivery strategies are unclear. We investigated the influence of the number of injected cells, resulting graft size, and possible paracrine mechanisms in this process. MI was induced in NOD-SCID mice (n=84) followed by injection of enriched hESC-CM at different dosages, hESC-non-CM derivatives, culture medium, or no injection. Cardiac function was monitored for 12 weeks with 9.4 T MRI (n=70). Grafts were identified by epifluorescence of a transgenic GFP marker and characterized by immunofluorescence. Vascularity and paracrine effects were investigated immunohistochemically. Transplantation of differentiated hESCs improved short, mid-, and long-term cardiac performance and survival, although only cardiomyocytes formed grafts. A mid-term (4 weeks) cardiomyocyte-specific enhancement was associated with elevated vascular density around the graft and attenuated compensatory remodeling. However, increasing the number of hESC-CM for injection did not enhance heart function further. Moreover, we observed that small graft size was associated with a better functional outcome. HESC-CM increased myocardial vascularization and enhanced heart function in mice after MI, but larger graft size was associated with reduced functional improvement. Future studies should focus on advanced delivery strategies and mechanisms of action rather than increasing graft size.
The pathogenesis of Crohn's disease involves a mucosal inflammatory response affecting the barrier function of the gut. Myofibroblasts directly underlining the intestinal epithelium may have a regulatory role in immune-mediated barrier disruption. A coculture system of T84 epithelial and CCD-18Co myofibroblasts was established in order to mimic the in situ spatial interactions between these cell types and to evaluate their role in barrier: integrity. Lamina propria mononuclear cells (LPMC) were introduced in co- and monocultures. Effects of immune cells on barrier integrity was determined by measuring resistance and permeability for macromolecules. Introduction of LPMC in both culture systems caused a time-dependent decrease in barrier integrity. This was found to be less pronounced in cocultures indicating a regulatory role for mesenchymal cells. The effects were also found to depend on the route of LPMC stimulation. Additional analyses suggested that the regulatory role of myofibroblasts in barrier integrity involves production of growth factors.
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