Placental Cdx2 Cells Regenerate Injured Myocardium

The limited regeneration of adult mammalian heart has prompted the need to recognize novel strategies that can restore contractile function in heart disease. However, in cell-based therapies the lack of an appropriate cell-type that can differentiate to cardiomyocytes in vivo persists as an ultimate unmet need. Our prior study demonstrates that experimental myocardial injury in pregnant mice triggers the flux of fetal cells via the maternal circulation into the injured heart where they undergo differentiation into diverse cardiac cell fates. Among those fetal cells, the expression of Caudal type homeobox2 (Cdx2); a trophoblast stem cell marker was unique. To understand the intriguing role of placental Cdx2 cells in cardiomyogenesis, we utilized a lineage-tracing strategy to label fetal-derived Cdx2 cells with enhanced green fluorescent protein (Cdx2-eGFP). Cdx2-eGFP cells were characterized and assayed for cardiac differentiation in vitro and in vivo using a mouse model of myocardial infarction. Cdx2-eGFP cells clonally proliferated and differentiated into spontaneously beating cardiomyocytes and vascular cells in vitro , signifying a multipotent nature compared to the Cdx2 negative cell population. When administered via tail vein to infarcted wild-type male mice, Cdx2-eGFP cells selectively and robustly homed to the injured heart and differentiated to cardiomyocytes and blood vessels, significantly improving the contractility noted by magnetic resonance imaging. Proteomics and immune transcriptomics studies of Cdx2-eGFP cells compared to embryonic stem (ES) cells reveal that they appear to retain ‘stem’-related functions of ES cells, but exhibit unique signatures for homing and survival in addition to being immunologically naive. Blocking CXCR4, during the migration of Cdx2-eGFP cells to SDF1α suggested a possible role for SDF1-CXCR4 signaling in the mechanistic basis of homing. Advancing towards a translational role, we demonstrate that CDX2 expressing cells can be isolated from the chorionic region of human term placenta. Our results herein may represent a paradigmatic shift in the way we approach early embryonic lineages and cell fate choices and will establish the translational potential of placental Cdx2 cells for cardiac repair.