Browsing by Subject "Cardiomyocytes"

Now showing 1 - 3 of 3
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    Adult Bone Marrow–derived Cells Do Not Acquire Functional Attributes of Cardiomyocytes When Transplanted into Peri-infarct Myocardium
    (Elsevier, 2008-06-01) Scherschel, John A.; Soonpaa, Mark H.; Srour, Edward F.; Field, Loren J.; Rubart, Michael; Microbiology and Immunology, School of Medicine
    (BM) cells after being directly transplanted into the ischemically injured heart remains a controversial issue. In this study, we investigated the ability of transplanted BM cells to develop intracellular calcium ([Ca2+] i ) transients in response to membrane depolarization in situ. Low-density mononuclear (LDM) BM cells, c-kit-enriched (c-kitenr) BM cells, and highly enriched lin– c-kit+ BM cells were obtained from adult transgenic mice ubiquitously expressing enhanced green fluorescent protein (EGFP), and injected into peri-infarct myocardiums of nontransgenic mice. After 9–10 days the mice were killed, and the hearts were removed, perfused in Langendorff mode, loaded with the calcium-sensitive fluorophore rhod-2, and subjected to two-photon laser scanning fluorescence microscopy (TPLSM) to monitor action potential–induced [Ca2+] i transients in EGFP-expressing donor-derived cells and non-expressing host cardiomyocytes. Whereas spontaneous and electrically evoked [Ca2+] i transients were found to occur synchronously in host cardiomyocytes along the graft–host border and in areas remote from the infarct, they were absent in all of the >3,000 imaged BM-derived cells that were located in clusters throughout the infarct scar or peri-infarct zone. We conclude that engrafted BM-derived cells lack attributes of functioning cardiomyocytes, calling into question the concept that adult BM cells can give rise to substantive cardiomyocyte regeneration within the infarcted heart.
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    Analysis of differentiation capacity of Cfp1 null embyronic stem cells
    (2014) Bowen, Tamara R.; Skalnik, David Gordon; Marrs, James; Chang, Hua-Chen
    Epigenetics is defined as “the study of stable, often heritable, changes that influence gene expression that are not mediated by DNA sequence” (Fingerman et al., 2013). Epigenetic marks such as covalent histone modifications and DNA methylation are important for maintaining chromatin structure and epigenetic inheritance. Several proteins have been found to bind and/ or regulate epigenetic marks. One such protein, CXXC finger protein 1 (Cfp1) is an important chromatin regulator that binds to unmethylated CpG islands. It has been found to be essential for mammalian development. Mice lacking Cfp1 exhibit an embryonic- lethal phenotype. However, the function of Cfp1 can be studied using Cfp1 Null mouse ES cells, which are viable. Thus far, Cfp1 has been shown to be important for cell growth, cytosine methylation, histone modifications, subnuclear localization of Set1A histone H3K4 methyltransferase, and cellular differentiation. When Cfp1 Null ES cells are induced to differentiate by removal of Leukemia Inhibitory Factor (LIF), the cells are not able to turn off pluripotency markers such as Oct4 and alkaline phosphatase and fail to express differentiation markers such as Gata4 and Brachyury. In this study, we used established protocols to further examine the differentiation capacity of Cfp1 Null cells. Specifically, we tested the ability of Cfp1 Null ES cells to retain stem cell properties in the absence of LIF, differentiate into cardiomyocytes in the presence of TGF-β2 and differentiate into neuron precursors in the presence of retinoic acid (RA). While the differentiation effects of RA were inconclusive, Null cells were able to start differentiating in the absence of LIF, either as individual cells or EBs, and the presence of TGF-β2 when seeded on gelatin coated tissue culture dishes. However, no difference was seen between cells treated without LIF and those treated with TGF-β2. In both conditions, only a small portion of cells were able to differentiate, while the majority of the cell population retained stem cell characteristics. Cell growth and the differentiation capacity of Cfp1 Null cells were also compromised in comparison to WT cells. Thus, further supporting the need for the correct epigenetic patterns maintained by Cfp1 during cellular differentiation.
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    Genome Editing and Induced Pluripotent Stem Cell Technologies for Personalized Study of Cardiovascular Diseases
    (Springer Nature, 2018-04-17) Chun, Young Wook; Durbin, Matthew D.; Hong, Charles C.; Pediatrics, School of Medicine
    PURPOSE OF REVIEW: The goal of this review is to highlight the potential of induced pluripotent stem cell (iPSC)-based modeling as a tool for studying human cardiovascular diseases. We present some of the current cardiovascular disease models utilizing genome editing and patient-derived iPSCs. RECENT FINDINGS: The incorporation of genome-editing and iPSC technologies provides an innovative research platform, providing novel insight into human cardiovascular disease at molecular, cellular, and functional level. In addition, genome editing in diseased iPSC lines holds potential for personalized regenerative therapies. The study of human cardiovascular disease has been revolutionized by cellular reprogramming and genome editing discoveries. These exceptional technologies provide an opportunity to generate human cell cardiovascular disease models and enable therapeutic strategy development in a dish. We anticipate these technologies to improve our understanding of cardiovascular disease pathophysiology leading to optimal treatment for heart diseases in the future.