Cardiac Progenitor Cell Cycling Stimulated by Pim-1 Kinase

Cottage, Christopher T.; Bailey, Brandi; Fischer, Kimberlee M.; Avitabile, Daniele; Collins, Brett; Tuck, Savilla; Quijada, Pearl; Gude, Natalie; Álvarez, Roberto Baelo; Muraski, John A.; Sussman, Mark A.

doi:10.1161/circresaha.109.208629

Cited by 86 publications

(81 citation statements)

References 63 publications

(80 reference statements)

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“…The recognition that the adult heart harbors a compartment of multipotent c-kit-positive cardiac stem cells (CSCs) (15)(16)(17)(18)(19)(20)(21)(22)(23) and other progenitor cell classes (24)(25)(26)(27)(28)(29) capable of differentiating into cardiomyocytes and coronary vessels has raised the challenging question concerning their embryologic origin and role in cardiac cell turnover and regeneration. CSCs are stored in interstitial structures with the characteristics of stem cell niches and can divide symmetrically and asymmetrically, with the ability to self-renew and form a committed progeny (17,21,30).…”

Section: Introductionmentioning

confidence: 99%

Regenerating new heart with stem cells

Anversa

Kajstura²,

Rota³

et al. 2013

J. Clin. Invest.

142

126

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This article discusses current understanding of myocardial biology, emphasizing the regeneration potential of the adult human heart and the mechanisms involved. In the last decade, a novel conceptual view has emerged. The heart is no longer considered a postmitotic organ, but is viewed as a self-renewing organ characterized by a resident stem cell compartment responsible for tissue homeostasis and cardiac repair following injury. Additionally, HSCs possess the ability to transdifferentiate and acquire the cardiomyocyte, vascular endothelial, and smooth muscle cell lineages. Both cardiac and hematopoietic stem cells may be used therapeutically in an attempt to reverse the devastating consequences of chronic heart failure of ischemic and nonischemic origin. IntroductionOur understanding of the process of myocardial regeneration is currently under debate. Although the adult human heart is no longer considered a static organ unable to replace its parenchymal cells during the course of life, the rate of myocyte regeneration reported thus far varies dramatically. Minimal levels of myocyte turnover, which decrease with age, have been claimed (1-5), but results have also been obtained supporting continuous myocyte renewal at a remarkable degree (6-12). Independent from the extent of the process, the debate is further intensified by contrasting views regarding the origin of newly formed cardiomyocytes (13,14). These issues have important implications because knowledge of the magnitude of cell regeneration and the mechanisms involved may offer a novel dynamic perspective of cardiac homeostasis and myocardial biology. This information is critical for the identification of strategies aiming at the restoration of the functional and structural integrity of the failing human heart.The recognition that the adult heart harbors a compartment of multipotent c-kit-positive cardiac stem cells (CSCs) (15-23) and other progenitor cell classes (24-29) capable of differentiating into cardiomyocytes and coronary vessels has raised the challenging question concerning their embryologic origin and role in cardiac cell turnover and regeneration. CSCs are stored in interstitial structures with the characteristics of stem cell niches and can divide symmetrically and asymmetrically, with the ability to self-renew and form a committed progeny (17,21,30). But whether this stem cell pool is actually self-autonomous and fully distinct from HSCs in the bone marrow remains to be determined. c-kit-positive HSCs transdifferentiate and acquire the myocyte, endothelial cell, and smooth muscle cell lineage (31), suggesting that the bone marrow participates in the homeostatic control of the myocardium and the restoration of myocytes and coronary vessels following injury. Additionally, the possibility has been advanced that postmitotic myocytes dedifferentiate, acquire an immature cell phenotype, and then reenter the cell cycle and divide (32-35), representing an alternative or complementary modality of myocyte formation. In this Review, we discuss CSCs, HS...

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Section: Introductionmentioning

confidence: 99%

Regenerating new heart with stem cells

Anversa

Kajstura²,

Rota³

et al. 2013

J. Clin. Invest.

142

126

View full text Add to dashboard Cite

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“…In zebrafish, Numb is required for heart left-right asymmetric morphogenesis via regulation of Notch signaling (Niikura et al, 2006). In mice, Numb is reportedly expressed in adult cardiac progenitor cells and is asymmetrically distributed during progenitor asymmetric division (Cottage et al, 2010;Mishra et al, 2011). Additionally, we have shown that NFPs are essential for epicardial cells entering into myocardium (Wu et al, 2010).…”

Section: Introductionmentioning

confidence: 80%

Numb family proteins are essential for cardiac morphogenesis and progenitor differentiation

Zhao

Guo

et al. 2014

Development

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Numb family proteins (NFPs), including Numb and numb-like (Numbl), are cell fate determinants for multiple progenitor cell types. Their functions in cardiac progenitor differentiation and cardiac morphogenesis are unknown. To avoid early embryonic lethality and study NFP function in later cardiac development, Numb and Numbl were deleted specifically in heart to generate myocardial doubleknockout (MDKO) mice. MDKOs were embryonic lethal and displayed a variety of defects in cardiac progenitor differentiation, cardiomyocyte proliferation, outflow tract (OFT) and atrioventricular septation, and OFT alignment. By ablating NFPs in different cardiac populations followed by lineage tracing, we determined that NFPs in the second heart field (SHF) are required for OFT and atrioventricular septation and OFT alignment. MDKOs displayed an SHF progenitor cell differentiation defect, as revealed by a variety of methods including mRNA deep sequencing. Numb regulated cardiac progenitor cell differentiation in an endocytosis-dependent manner. Studies including the use of a transgenic Notch reporter line showed that Notch signaling was upregulated in the MDKO. Suppression of Notch1 signaling in MDKOs rescued defects in p57 expression, proliferation and trabecular thickness. Further studies showed that Numb inhibits Notch1 signaling by promoting the degradation of the Notch1 intracellular domain in cardiomyocytes. This study reveals that NFPs regulate trabecular thickness by inhibiting Notch1 signaling, control cardiac morphogenesis in a Notch1-independent manner, and regulate cardiac progenitor cell differentiation in an endocytosis-dependent manner. The function of NFPs in cardiac progenitor differentiation and cardiac morphogenesis suggests that NFPs might be potential therapeutic candidates for cardiac regeneration and congenital heart diseases.

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“…6,32-40 Furthermore, we were able to identify genes within the upregulated group that have a heart-associated function (the Table) such as thbs4b, jak2a, txnipa, pim1, slc4a1a, and cxcr4b. 39,[41][42][43][44][45] A number of proproliferative genes were also shown to be upregulated in the wild-type sample compared with the dnHIF1␣ sample (the Table). 46 -51 Although the positive aspects of dedifferentiation have not been intensely investigated, we were able to identify a couple of genes that have been linked to this phenomenon, namely jak2a and cxcr4b, albeit these are most commonly associated with cancer cell dedifferentiation.…”

Section: Mechanisms Of Hypoxia During Heart Regenerationmentioning

confidence: 97%

Hypoxia Induces Myocardial Regeneration in Zebrafish

et al. 2012

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Background-Hypoxia plays an important role in many biological/pathological processes. In particular, hypoxia is associated with cardiac ischemia. which, although initially inducing a protective response, will ultimately lead to the death of cardiomyocytes and loss of tissue, severely affecting cardiac functionality. Although myocardial damage/loss remains an insurmountable problem for adult mammals, the same is not true for adult zebrafish, which are able to completely regenerate their heart after extensive injury. Myocardial regeneration in zebrafish involves the dedifferentiation and proliferation of cardiomyocytes to replace the damaged/missing tissue; at present, however, little is known about what factors regulate this process. Methods and Results-We surmised that ventricular amputation would lead to hypoxia induction in the myocardium of zebrafish and that this may play a role in regulating the regeneration of the missing cardiac tissue. Using a combination of O 2 perturbation, conditional transgenics, in vitro cell culture, and microarray analysis, we found that hypoxia induces cardiomyocytes to dedifferentiate and proliferate during heart regeneration in zebrafish and have identified a number of genes that could play a role in this process. Conclusion-These results indicate that hypoxia plays a positive role during heart regeneration, which should be taken into account in future strategies aimed at inducing heart regeneration in humans. (Circulation. 2012;126:3017-3027.)

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Cardiac Progenitor Cell Cycling Stimulated by Pim-1 Kinase

Cited by 86 publications

References 63 publications

Regenerating new heart with stem cells

Regenerating new heart with stem cells

Numb family proteins are essential for cardiac morphogenesis and progenitor differentiation

Hypoxia Induces Myocardial Regeneration in Zebrafish

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