A specific human fetal heart RNA has been discovered, which has the ability to induce myocardial cell formation from mouse embryonic and human-induced pluripotent stem cells in culture. In this study, commercially obtained RNA from human fetal heart was cloned, sequenced, and synthesized using standard laboratory approaches. Molecular analyses of the specific fetal cardiac-inducing RNA (CIR), revealed that it is a fragment of N-sulfoglucosaminesulfohydrolase and the caspase recruitment domain family member 14 precursor. Stem cells transfected with CIRs often form into spindle-shaped cells characteristic of cardiomyocytes,and express the cardiac-specific contractile protein marker, troponin-T, in addition to tropomyosin and α-actinin as detected by immunohistochemical staining. Expression of these contractile proteins showed organization into sarcomeric myofibrils characteristic of striated cardiac muscle cells. Computer analyses of the RNA secondary structures of the active CIR show significant similarities to a RNA from salamander or myofibril-inducing RNA (MIR), which also promotes non-muscle cells to differentiate into cardiac muscle. Thus, these two RNAs, salamander MIR and the newly discovered human-cloned CIR reported here, appear to have evolutionarily conserved secondary structures suggesting that both play major roles in vertebrate heart development and, particularly, in the differentiation of cardiomyocytes from non-muscle cells during development.
Heart disease is the number one killer in the USA, making cardiogenesis and its related pathways a relevant area of study for improving health and life expectancy. The Mexican salamander (axolotl), Ambystoma mexicanum, provides an excellent vertebrate animal model for studying myofibrillogenesis due to its naturally occurring cardiac nonfunction mutation. Homozygous recessive embryos do not develop normal hearts due to a lack of myofibril formation. In previous studies, myofibril-inducing ribonucleic acid (MIR) from the normal wild-type axolotl genome was found to rescue mutant nonfunctioning hearts through restoration of tropomyosin levels followed by normal myofibril formation. Our purpose in this study is to identify and characterize functional homologs for the MIR from human fetal heart ribonucleic acid (RNA). After randomized cloning of human fetal heart RNA, 396 clones were analyzed for rescuing ability by using mutant heart rescue bioassays and confocal microscopy. By these analyses, we discovered a functional homolog of MIR from human fetal heart RNA, which is associated with the mitochondrial cytochrome c oxidase subunit II gene. This RNA came from our clone #30 and induces tropomyosin synthesis and myofibrillogenesis in mutant axolotl hearts which ordinarily do not synthesize tropomyosin or form organized myofibrils. Clone #30, a mitochondrial RNA molecule associated with human cytochrome c oxidase, serves as a functional homolog of MIR, leading to tropomyosin production, organized myofibrils, and beating cardiac tissue in mutant hearts. These findings hold great potential for the treatment and repair of damaged hearts in patients who have suffered from myocardial infarctions and other heart diseases.
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