Your search keyword '"Leri, Annarosa"' showing total 19 results

1. Notch signaling modulates the electrical behavior of cardiomyocytes.

Author

Borghetti, Giulia, Eisenberg, Carol A., Signore, Sergio, Sorrentino, Andrea, Kaur, Keerat, Andrade-Vicenty, Alejandro, Edwards, John G., Nerkar, Mriganka, Qanud, Khaled, Dong Sun, Goichberg, Polina, Leri, Annarosa, Anversa, Piero, Eisenberg, Leonard M., Jacobson, Jason T., Hintze, Thomas H., and Rota, Marcello

Subjects

HEART cells, ACTION potentials, NOTCH signaling pathway

Abstract

Notch receptor signaling is active during cardiac development and silenced in myocytes after birth. Conversely, outward K+ Kv currents progressively appear in postnatal myocytes leading to shortening of the action potential (AP) and acquisition of the mature electrical phenotype. In the present study, we tested the possibility that Notch signaling modulates the electrical behavior of cardiomyocytes by interfering with Kv currents. For this purpose, the effects of Notch receptor activity on electrophysiological properties of myocytes were evaluated using transgenic mice with inducible expression of the Notch1 intracellular domain (NICD), the functional fragment of the activated Notch receptor, and in neonatal myocytes after inhibition of the Notch transduction pathway. By patch clamp, NICD-overexpressing cells presented prolonged AP duration and reduced upstroke amplitude, properties that were coupled with reduced rapidly activating Kv and fast Na+ currents, compared with cells obtained from wild-type mice. In cultured neonatal myocytes, inhibition of the proteolitic release of NICD with a γ-secretase antagonist increased transcript levels of the Kv channel-interacting proteins 2 (KChIP2) and enhanced the density of Kv currents. Collectively, these results indicate that Notch signaling represents an important regulator of the electrophysiological behavior of developing and adult myocytes by repressing, at least in part, repolarizing Kv currents. [ABSTRACT FROM AUTHOR]

Published

2018

2. Mechanisms of Myocardial Regeneration

Author

Leri, Annarosa, Kajstura, Jan, and Anversa, Piero

Subjects

*HEART cells, *MULTIPOTENT stem cells, *CELL cycle, *STEM cells, *HEART cytology, *PLURIPOTENT stem cells

Abstract

Traditionally, the adult heart has been viewed as a terminally differentiated postmitotic organ in which the number of cardiomyocytes is established at birth and these cells persist throughout the life span of the organ and organism. However, the discovery that cardiac stem cells live in the heart and differentiate into the various cardiac cell lineages has dramatically changed our understanding of myocardial biology. Deciphering the biological processes that lead to myocyte renewal is a challenging task. Cardiac regeneration may be accomplished by (1) commitment of multipotent stem cells that generate all specialized lineages within the parenchyma, (2) activation of unipotent progenitors with restricted differentiation potential, (3) replication of pre-existing differentiated cells, (4) transdifferentiation of exogenous progenitors that undergo plastic conversion into cells different from the organ of origin, and (5) dedifferentiation of cardiomyocytes that re-enter the cell cycle and divide. These multiple mechanisms of cell growth may act in concert to regenerate complex structures and restore the function of the target organ. [ABSTRACT FROM AUTHOR]

Published

2011

3. Spontaneous Calcium Oscillations Regulate Human Cardiac Progenitor Cell Growth.

Author

Ferreira-Martins, João, Rondon-Clavo, Carlos, Tugal, Derin, Korn, Justin A., Rizzi, Roberto, Padin-Iruegas, Maria Elena, Ottolenghi, Sergio, De Angelis, Antonella, Urbanek, Konrad, Ide-Iwata, Noriko, D'Amario, Domenico, Hosoda, Toni, Leri, Annarosa, Kajstura, Jan, Anversa, Piero, and Rota, Marcello

Subjects

INTRACELLULAR calcium, HEART cells, CELL communication, GROWTH factors, CALCIUM

Abstract

The article focuses on a research that aims to identify the pathways that regulate intracellular Ca2+ in human cardiac progenitor cells (hCPCs) and to evaluate whether Ca2+ are triggered by hCPCs and cardiomyocytes' interaction. It states that Ca2+ indicator and Fluo-3 and 2-photon microscopy were used to measure cytosolic Ca2+ levels. Results show that hCPCs show spontaneous elevations in intracellular Ca2+.

Published

2009

4. Clonality of mouse and human cardiomyogenesis in vivo.

Author

Hosoda, Toru, D'Amario, Domenico, Cabral-Da-Silva, Mauricio Castro, Zheng, Hanqiao, Padin-lruegas, M. Elena, Ogorek, Barbara, Ferreira-Martins, João, Yasuzawa-Amano, Saori, Amano, Katsuya, Ide-Iwata, Noriko, Cheng, Wei, Rota, Marcello, Urbanek, Konrad, Kajstura, Jan, Anversa, Piero, and Leri, Annarosa

Subjects

HEART cells, MUSCLE cells, MICE physiology, HUMAN genome, LENTIVIRUS diseases, FIBROBLASTS, CELL populations, MYOCARDIAL infarction

Abstract

An analysis of the clonality of cardiac progenitor cells (CPCs) and myocyte turnover in vivo requires genetic tagging of the undifferentiated cells so that the clonal marker of individual mother cells is traced in the specialized progeny. CPC niches in the atria and apex of the mouse heart were infected with a lentivirus carrying EGFP, and the destiny of the tagged cells was determined 1-5 months later. A common integration site was identified in isolated CPCs, cardiomyocytes, endothelial cells (ECs), and fibroblasts, documenting CPC self-renewal and multipotentiality and the clonal origin of the differentiated cell populations. Subsequently, the degree of EGFP-lentiviral infection of CPCs was evaluated 2-4 days after injection, and the number of myocytes expressing the reporter gene was measured 6 months later. A BrdU pulse-chasing protocol was also introduced as an additional assay for the analysis of myocyte turnover. Over a period of 6 months, each EGFP-positive CPC divided approximately eight times generating 230 cardiomyocytes; this value was consistent with the number of newly formed cells labeled by BrdU. To determine whether, human CPCs (hCPCs) are self-renewing and multipotent, these cells were transduced with the EGFP-lentivirus and injected after acute myocardial infarction in immunosuppressed rats. hCPCs, myocytes, ECs, and fibroblasts collected from the regenerated myocardium showed common viral integration sites in the human genome. Thus, our results indicate that the adult heart contains a pool of resident stem cells that regulate cardiac homeostasis and repair. [ABSTRACT FROM AUTHOR]

Published

2009

5. Myocardial Induction of Nucleostemin in Response to Postnatal Growth and Pathological Challenge.

Author

Siddiqi, Sailay, Gude, Natalie, Hosoda, Toru, Muraski, John, Rubio, Marta, Emmanuel, Gregory, Fransioli, Jenna, Vitale, Serena, Parolin, Carola, D'Amario, Domenico, Schaefer, Erik, Kajstura, Jan, Leri, Annarosa, Anversa, Piero, and Sussman, Mark A.

Subjects

HEART cells, HEART cytology, STEM cell research, TELOMERASE, CYTOLOGICAL research

Abstract

The article reports on myocardial induction of nucleostemin in response to postnatal growth and pathological challenge. It is found that nucleostemin is present in young myocardium and is also induced following cardiomyopathic injury. Nucleostemin expression in cardiomyocytes is said to be induced by fibroblast growth factor-2 and accumulates in response to Pim-1 kinase activity.

Published

2008

6. The Human Heart: A Self-Renewing Organ.

Author

Kajstura, Jan, Hosoda, Toru, Bearzi, Claudia, Rota, Marcello, Maestroni, Silvia, Urbanek, Konrad, Leri, Annarosa, and Anversa, Piero

Subjects

CARDIOVASCULAR system, HEART, HEART cells, MUSCLE cells, MYOCARDIUM, DNA, MITOSIS, CYTOKINESIS, STEM cells

Abstract

The dogma that the heart is a static organ which contains an irreplaceable population of cardiomyocytes prevailed in the cardiovascular field for the last several decades. However, the recent identification of progenitor cells that give rise to differentiated myocytes has prompted a re-interpretation of cardiac biology. The heart cannot be viewed any longer as a postmitotic organ characterized by a predetermined number of myocytes that is defined at birth and is preserved throughout life. The myocardium constitutes a dynamic entity in which new young parenchymal cells are formed to substitute old damaged dying myocytes. The regenerative ability of the heart was initially documented with a classic morphometric approach and more recently with the demonstration that DNA synthesis, mitosis, and cytokinesis take place in the newly formed myocytes of the normal and pathologic heart. Importantly, replicating myocytes correspond to the differentiated progeny of cardiac stem cells. These findings point to the possibility of novel therapeutic strategies for the diseased heart. [ABSTRACT FROM AUTHOR]

Published

2008

7. Bone marrow cells adopt the cardiomyogenic fate in vivo.

Author

Rota, Marcello, Kajstura, Jan, Hosoda, Toru, Bearzi, Claudia, Vitale, Serena, Esposito, Grazia, Laffaldano, Grazia, Padin-Iruegas, M. Elena, Gonzalez, Arantxa, Rizzi, Roberto, Small, Narissa, Muraski, John, Alvarez, Roberto, Xiongwen Chen, Urbanek, Konrad, Bolli, Roberto, Houser, Steven R., Leri, Annarosa, Sussman, Mark A., and Anversa, Piero

Subjects

BONE marrow cells, HEART cells, MYOCARDIAL infarction, STEM cells, MUSCLE cells, PHENOTYPES, CELL fusion

Abstract

The possibility that adult bone marrow cells (BMCs) retain a remark- able degree of developmental plasticity and acquire the cardiomyocyte lineage after infarction has been challenged, and the notion of BMC transdifferentiation has been questioned. The center of the controversy is the lack of unequivocal evidence in favor of myocardial regeneration by the injection of BMCs in the infarcted heart. Because of the interest in cell-based therapy for heart failure, several approaches including gene reporter assay, genetic tagging, cell genotyping, PCR-based detection of donor genes, and direct immunofluorescence with quantum dots were used to prove or disprove BMC transdifferentiation. Our results indicate that BMCs engraft, survive, and grow within the spared myocardium after infarction by forming junctional complexes with resident myocytes. BMC5 and myocytes express at their interface connexin 43 and N-cadherin, and this interaction may be critical for BMCs to adopt the card iomyogenic fate. With time, a large number of myocytes and coronary vessels are generated. Myocytes show a diploid DNA content and carry, at most, two sex chromosomes. Old and new myocytes show synchronicity in calcium transients, providing strong evidence in favor of the functional coupling of these two cell populations. Thus, BMC5 transdifferentiate and acquire the cardiomyogenic and vascular phenotypes restoring the infarcted heart. Together, our studies reveal that locally delivered BMC5 generate de novo myocardium composed of integrated cardiomyocytes and coronary vessels. This process occurs independently of cell fusion and ameliorates structurally and functionally the outcome of the heart after infarction. [ABSTRACT FROM AUTHOR]

Published

2007

8. Human cardiac stem cells.

Author

Bearzi, Claudia, Rota, Marcello, Hosoda, Toru, Tillmanns, Jochen, Nascimbene, Angelo, De Angelis, Antonella, Yasuzawa-Amano, Saori, Trofimova, Irma, Siggins, Robert W., LeCapitaine, Nicole, Cascapera, Stefano, Beltrami, Antonio P., D'Alessandro, David A., Zias, Elias, Quaini, Federico, Urbanek, Konrad, Michler, Robert E., Bolli, Roberto, Kajstura, Jan, and Leri, Annarosa

Subjects

STEM cells, HEART cells, MYOCARDIUM, MUSCLE cells, HEART diseases

Abstract

The identification of cardiac progenitor cells in mammals raises the possibility that the human heart contains a population of stem cells capable of generating cardiomyocytes and coronary vessels. The characterization of human cardiac stem cells (hCSCs) would have important clinical implications for the management of the failing heart. We have established the conditions for the isolation and expansion of c-kit-positive hCSCs from small samples of myocardium. Additionally, we have tested whether these cells have the ability to form functionally competent human myocardium after infarction in immunocompromised animals. Here, we report the identification in vitro of a class of human c-kit-positive cardiac cells that possess the fundamental properties of stem cells: they are self-renewing, clonogenic, and multipotent. hCSCs differentiate predominantly into cardiomyocytes and, to a lesser extent, into smooth muscle cells and endothelial cells. When locally injected in the infarcted myocardium of immunodeficient mice and immunosuppressed rats, hCSCs generate a chimeric heart, which contains human myocardium composed of myocytes, coronary resistance arterioles, and capillaries. The human myocardium is structurally and functionally integrated with the rodent myocardium and contributes to the performance of the infarcted heart. Differentiated human cardiac cells possess only one set of human sex chromosomes excluding cell fusion. The lack of cell fusion was confirmed by the Cre-lox strategy. Thus, hCSCs can be isolated and expanded in vitro for subsequent autologous regeneration of dead myocardium in patients affected by heart failure of ischemic and nonischemic origin. [ABSTRACT FROM AUTHOR]

Published

2007

9. Cardiac Regeneration

Author

Anversa, Piero, Leri, Annarosa, and Kajstura, Jan

Subjects

*MUSCLE cells, *MUSCLE regeneration, *STEM cells, *VASCULAR smooth muscle, *REGULATION of cell growth, *DNA synthesis, *HEART cells

Abstract

The role and even the existence of new myocyte formation in the adult heart remain controversial. Documentation of cell cycle regulators, deoxyribonucleic acid synthesis, and mitotic images has only in part modified the view that myocardial growth can be accomplished exclusively from hypertrophy of an irreplaceable population of differentiated myocytes. However, myocyte regeneration and death occur physiologically, and these cellular processes are enhanced in pathologic states. These observations have challenged the view of the heart as a postmitotic organ and have proposed a new paradigm in which parenchymal and non-parenchymal cells are continuously replaced by newly formed younger populations of myocytes as well as by vascular smooth muscle and endothelial cells. Heart homeostasis is regulated by a stem cell compartment characterized by multipotent cardiac stem cells that possess the ability to acquire the distinct cell lineages of the myocardium. Similarly, adult bone marrow cells are able to differentiate into cells beyond their own tissue boundary and create cardiomyocytes and coronary vessels. This process has been termed developmental plasticity or transdifferentiation. Because of these properties, bone marrow cells and cardiac stem cells have been employed experimentally in the reconstitution of dead myocardium after infarction. These cell classes hold promise for the treatment of heart failure in humans. [Copyright &y& Elsevier]

Published

2006

10. Bcl-2 overexpression promotes myocyte proliferation.

Author

Limana, Federica, Urbanek, Konrad, Chimenti, Stefano, Quaini, Federico, Leri, Annarosa, Kajstura, Jan, Nadal-Ginard, Bernardo, Izumo, Seigom, and Anversa, Piero

Subjects

HEART cells, CORONARY disease

Abstract

Analyzes the population dynamics of the cells in the heart of transgenic mice under the control of alpha-myosin heavy chain promoter. Influence of Bcl-2 on the developmental biology; Formation of mitotic spindle and contractile ring in replicating cells; Viability of the ischemic brain and myocardium.

Published

2002

11. Myocyte Growth and Cardiac Repair

Author

Anversa, Piero, Leri, Annarosa, Kajstura, Jan, and Nadal-Ginard, Bernardo

Subjects

*HEART cells, *REGENERATION (Biology), *APOPTOSIS

Abstract

Introduced several decades ago, the dogma persists that ventricular myocytes are terminally differentiated cells and cardiac repair by myocyte regeneration is completely inhibited shortly after birth. On the basis that cardiac myocytes are unable to divide in the adult heart, myocyte growth under physiologic and pathologic conditions is believed to be restricted to cellular hypertrophy. Evidence is presented to indicate that this old paradigm has to be changed to include myocyte replication as a significant component of the cellular processes of ventricular remodeling. Importantly, myocyte death, apoptotic and necrotic in nature, has to be regarded as an additional critical variable of the multifactorial events implicated in the alterations of cardiac anatomy and myocardial structure of the decompensated heart. Methodologies are currently available to recognize and measure quantitatively the contribution of myocyte size, number and death to the adaptation of the overloaded heart and its progression to cardiac failure. [ABSTRACT FROM AUTHOR]

Published

2002

12. Mobilized bone marrow cells repair the infarcted heart, improving function and survival.

Author

Orlic, Donald, Kajstura, Jan, Chimenti, Stefano, Limana, Federica, Jakoniuk, Igor, Quaini, Federico, Nadal-Ginard, Bernardo, Bodine, David M., Leri, Annarosa, and Anversa, Piero

Subjects

HEART cells, MYOCARDIAL infarction

Abstract

Examines the transplantation of cardiomyocytes for repairing myocardial infarction disease. Mobilization of the bone marrow cells for repairing the infarcted heart; Conduction of echocardiography and hemodynamics for the examination; Use of cytoplasmic and nuclear markers for cell differentiation.

Published

2001

13. Corrigendum: Pim-1 regulates cardiomyocyte survival downstream of Akt.

Author

Muraski, John A, Rota, Marcello, Misao, Yu, Fransioli, Jenna, Cottage, Christopher, Gude, Natalie, Esposito, Grazia, Delucchi, Francesca, Arcarese, Michael, Alvarez, Roberto, Siddiqi, Sailay, Emmanuel, Gregory N, Wu, Weitao, Fischer, Kimberlee, Martindale, Joshua J, Glembotski, Christopher C, Leri, Annarosa, Kajstura, Jan, Magnuson, Nancy, and Berns, Anton

Subjects

HEART cells

Abstract

A correction to the article "Pim-1 regulates cardiomyocyte survival downstream of Akt," by John A. Muraski and colleagues, is presented.

Published

2008

14. Cardiac Stem Cells: Biology and Clinical Applications.

Author

Goichberg, Polina, Chang, Jerway, Liao, Ronglih, and Leri, Annarosa

Subjects

*HEART cells, *STEM cells, *HEART diseases, *HEART failure, *HEART transplantation

Abstract

Significance: Heart disease is the primary cause of death in the industrialized world. Cardiac failure is dictated by an uncompensated reduction in the number of viable and fully functional cardiomyocytes. While current pharmacological therapies alleviate the symptoms associated with cardiac deterioration, heart transplantation remains the only therapy for advanced heart failure. Therefore, there is a pressing need for novel therapeutic modalities. Cell-based therapies involving cardiac stem cells (CSCs) constitute a promising emerging approach for the replenishment of the lost tissue and the restoration of cardiac contractility. Recent Advances: CSCs reside in the adult heart and govern myocardial homeostasis and repair after injury by producing new cardiomyocytes and vascular structures. In the last decade, different classes of immature cells expressing distinct stem cell markers have been identified and characterized in terms of their growth properties, differentiation potential, and regenerative ability. Phase I clinical trials, employing autologous CSCs in patients with ischemic cardiomyopathy, are being completed with encouraging results. Critical Issues: Accumulating evidence concerning the role of CSCs in heart regeneration imposes a reconsideration of the mechanisms of cardiac aging and the etiology of heart failure. Deciphering the molecular pathways that prevent activation of CSCs in their environment and understanding the processes that affect CSC survival and regenerative function with cardiac pathologies, commonly accompanied by alterations in redox conditions, are of great clinical importance. Future Directions: Further investigations of CSC biology may be translated into highly effective and novel therapeutic strategies aiming at the enhancement of the endogenous healing capacity of the diseased heart. Antioxid. Redox Signal. 21, 2002-2017. [ABSTRACT FROM AUTHOR]

Published

2014

15. Growth Properties of Cardiac Stem Cells Are a Novel Biomarker of Patients' Outcome After Coronary Bypass Surgery.

Author

D'Amario, Domenico, Leone, Antonio M., Iaconelli, Antonio, Luciani, Nicola, Gaudino, Mario, Kannappan, Ramaswamy, Manchi, Melissa, Severino, Anna, Sang Hun Shin, Graziani, Francesca, Biasillo, Gina, Macchione, Andrea, Smaldone, Costantino, De Maria, Giovanni Luigi, Cellini, Carlo, Siracusano, Andrea, Ottaviani, Lara, Massetti, Massimo, Goichberg, Polina, and Leri, Annarosa

Subjects

*STEM cell treatment, *HEART cells, *CORONARY artery bypass, *CELL growth, *BIOMARKERS

Abstract

Background--The efficacy of bypass surgery in patients with ischemic cardiomyopathy is not easily predictable; preoperative clinical conditions may be similar, but the outcome may differ significantly. We hypothesized that the growth reserve of cardiac stem cells (CSCs) and circulating cytokines promoting CSC activation are critical determinants of ventricular remodeling in this patient population. Methods and Results--To document the growth kinetics of CSCs, population-doubling time, telomere length, telomerase activity, and insulin-like growth factor-1 receptor expression were measured in CSCs isolated from 38 patients undergoing bypass surgery. Additionally, the blood levels of insulin-like growth factor-l, hepatocyte growth factor, and vascular endothelial growth factor were evaluated. The variables of CSC growth were expressed as a function of the changes in wall thickness, chamber diameter and volume, ventricular mass-to-chamber volume ratio, and ejection fraction, before and 12 months alter surgery. A high correlation was found between indices of CSC function and cardiac anatomy. Negative ventricular remodeling was not observed if CSCs retained a significant growth reserve. The high concentration of insulin-like growth factor-1 systemically pointed to the insulin-like growth factor-1-insulin-like growth factor-1 receptor system as a major player in the adaptive response of the myocardium, hepatocyte growth factor, a mediator of CSC migration, was also high in these patients preoperatively, as was vascular endothelial growth factor, possibly reflecting the vascular growth needed before bypass surgery. Conversely, a decline in CSC growth was coupled with wall thinning, chamber dilation, and depressed ejection fraction. Conclusions--The telomere-telomerase axis, population-doubling time, and insulin-like growth factor- 1 receptor expression in CSCs, together with a high circulating level of insulin-like growth factor-1, represent a novel biomarker able to predict the evolution of ischemic cardiomyopathy following revascularization. [ABSTRACT FROM AUTHOR]

Published

2014

16. Age-Associated Defects in EphA2 Signaling Impair the Migration of Human Cardiac Progenitor Cells.

Author

Goichberg, Polina, Kannappan, Ramaswamy, Cimini, Maria, Yingnan Bai, Fumihiro Sanada, Sorrentino, Andrea, Kajstura, Jan, Rota, Marcello, Anversa, Piero, and Leri, Annarosa

Subjects

*AGING, *PROGENITOR cells, *STEM cell research, *HEART cells, *HEART cytology

Abstract

Background--Aging negatively impacts on the function of resident human cardiac progenitor cells (hCPCs). Effective regeneration of the injured heart requires mobilization of hCPCs to the sites of damage. In the young heart, signaling by the guidance receptor EphA2 in response to the ephrin A1 ligand promotes hCPC motility and improves cardiac recovery after infarction. Methods and Results--We report that old hCPCs are characterized by cell-autonomous inhibition of their migratory ability ex vivo and impaired translocation in vivo in the damaged heart. EphA2 expression was not decreased in old hCPCs; however, the elevated level of reactive oxygen species in aged cells induced post-translational modifications of the EphA2 protein. EphA2 oxidation interfered with ephrin Al-stimulated receptor auto-phosphorylation, activation of Src family kinases, and caveolin-l-mediated internalization of the receptor. Cellular aging altered the EphA2 endocytic route, affecting the maturation of EphA2-containing endosomes and causing premature signal termination. Overexpression of functionally intact EphA2 in old hCPCs corrected the defects in endocytosis and downstream signaling, enhancing cell motility. Based on the ability of phenotypically young hCPCs to respond efficiently to ephrin A1, we developed a novel methodology for the prospective isolation of live hCPCs with preserved migratory capacity and growth reserve. Conclusions--Our data demonstrate that the ephrin A1/EphA2 pathway may serve as a target to facilitate trafficking of hCPCs in the senescent myocardium. Importantly, EphA2 receptor function can be implemented for the selection of hCPCs with high therapeutic potential, a clinically relevant strategy that does not require genetic manipulation of stem cells. [ABSTRACT FROM AUTHOR]

Published

2013

17. Regenerating new heart with stem cells.

Author

Anversa, Piero, Kajstura, Jan, Rota, Marcello, and Leri, Annarosa

Subjects

*STEM cells, *CARDIAC regeneration, *HOMEOSTASIS, *HEART cells, *VASCULAR endothelium, *HEART failure

Abstract

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. [ABSTRACT FROM AUTHOR]

Published

2013

18. Cardiomyogenesis in the Aging and Failing Human Heart.

Author

Kajstura, Jan, Rota, Marcello, Cappetta, Donato, Ogorek, Barbara, Arranto, Christian, Yingnan Bai, Ferreira-Martins, Joao, Signore, Sergio, Sanada, Fumihiro, Matsuda, Alex, Kostyla, James, Caballero, Maria-Virginia, Fiorini, Claudia, D'Alessandro, David A., Michler, Robert E., del Monte, Federica, Hosoda, Toru, Perrella, Mark A., Leri, Annarosa, and Buchholz, Bruce A.

Subjects

*HEART development, *HEART failure, *HEART cells, *RETROSPECTIVE studies, *VASCULAR endothelial cells, HEART aging

Abstract

Background--Two opposite views of cardiac growth are currently held; one views the heart as a static organ characterized by a large number of cardiomyocytes that are present at birth and live as long as the organism, and the other views the heart a highly plastic organ in which the myocyte compartment is restored several times during the course of life. Methods and Results--The average age of cardiomyocytes, vascular endothelial cells (ECs), and fibroblasts and their turnover rates were measured by retrospective 14C birth dating of cells in 19 normal hearts 2 to 78 years of age and in 17 explanted failing hearts 22 to 70 years of age. We report that the human heart is characterized by a significant turnover of ventricular myocytes, ECs, and fibroblasts, physiologically and pathologically. Myocyte, EC, and fibroblast renewal is very high shortly after birth, decreases during postnatal maturation, remains relatively constant in the adult organ, and increases dramatically with age. From 20 to 78 years of age, the adult human heart entirely replaces its myocyte, EC, and fibroblast compartment ≅8, ≅6, and ≅8 times, respectively. Myocyte, EC, and fibroblast regeneration is further enhanced with chronic heart failure. Conclusions--The human heart is a highly dynamic organ that retains a remarkable degree of plasticity throughout life and in the presence of chronic heart failure. However, the ability to regenerate cardiomyocytes, vascular ECs, and fibroblasts cannot prevent the manifestations of myocardial aging or oppose the negative effects of ischemic and idiopathic dilated cardiomyopathy. [ABSTRACT FROM AUTHOR]

Published

2012

19. Cardiac stem cells and myocardial disease

Author

Kajstura, Jan, Urbanek, Konrad, Rota, Marcello, Bearzi, Claudia, Hosoda, Toru, Bolli, Roberto, Anversa, Piero, and Leri, Annarosa

Subjects

*CARDIOMYOPATHIES, *HEART cells, *HEART diseases, *THERAPEUTICS, *MUSCLE cells

Abstract

Abstract: Recent data indicate that the heart is a self-renewing organ and contains a pool of progenitor cells (PCs). According to the new paradigm, this resident population of multipotent undifferentiated cells gives rise to myocytes, endothelial cells, smooth muscle cells and fibroblasts. Understanding the function of cardiac PCs is critical for the implementation of these cells in the treatment of the diseased human heart. However, cardiac repair is an extremely complex phenomenon. Efficient myocardial regeneration requires restoration of segmental and focal areas of myocardial scarring, replacement of damaged coronary arteries, arterioles and capillaries, and substitution of hypertrophied poorly contracting myocytes with smaller better functioning parenchymal cells. To achieve these goals, the acquisition of a more profound knowledge of the biology of cardiac PCs cells and their fate following pathologic insults represents an essential need. [Copyright &y& Elsevier]

Published

2008