Discovery of cardiac stem cells may advance regenerative heart therapy

November 22, 2006

An immediate early publication of the journal Cell, published by Cell Press, on Nov. 22, 2006 points to the possible existence of master cardiac stem cells with the capacity to produce all three major tissues of the mammalian heart. A companion Cell paper also published online reports the discovery of a second population of cardiac progenitors, which are capable of forming both cardiac muscle and the smooth muscle found in the heart's blood vessel walls.

Together with similar findings reported in the November issue of the journal Developmental Cell, also a Cell Press publication, the findings challenge the notion that the heart's diverse cell types--including cardiac muscle, smooth muscle, and the endothelial cells that line blood vessels--stem from "non-overlapping embryonic precursors derived from distinct origins," according to the researchers.

The findings may also have important implications for regenerative medicine aimed at cardiac repair in patients with congenital or acquired heart disease, according to the researchers.

"It's a surprise that a single cell can give rise to all of these tissues and structures in the heart," said Kenneth Chien of Massachusetts General Hospital and Harvard Medical School. "The heart may look more like blood than we thought," he added, referring to the fact that single so-called hematopoietic stem cells can give rise to all of the cell types found in blood.

"This changes the way we think about organ development," said Howard Hughes Medical Institute investigator Stuart Orkin, the author of the companion paper from the Children's Hospital Boston. "Rather than different cell types coming together, the heart appears to develop from a common set of progenitors or stem cells. This may be a more economical method."

Chien's team earlier found a group of cardiac muscle progenitors called islet-1 (isl1+) cells in heart tissue from newborn rats, mice, and humans. The cells are defined by the presence of an isl1 protein.

To further examine the developmental potential of these isl1 progenitor cells in the current study, the researchers traced the fate of these cells in the hearts of mice. They found that the isl1 precursors produce not only cardiac muscle but also smooth muscle, endothelial, pacemaker, and other nonmuscle cell lineages. They then showed that the isl1 cells could be obtained from embryonic stem cells.

"These studies document a developmental paradigm for cardiogenesis, where muscle and endothelial lineage diversification arises from a single cell-level decision of a multipotent isl1+ cardiovascular progenitor cell," Chien said.

In the second study, Orkin and his colleagues isolated cells from a mouse embryo that expressed a cardiac-specific gene, called Nkx2.5+. They found that the Nkx2.5 cells spontaneously differentiated primarily into cardiac muscle cells and conduction system cells. The heart's conduction system carries the electrical impulses that allow it to beat.

Surprisingly, they found, some of the precursor cells took on a smooth muscle fate.

They then isolated Nkx2.5 cells derived from embryonic stem cells and found that some of the cells also expressed a second gene, c-kit. It was the c-kit+Nkx2.5+ cells that had the ability to expand and produce both cardiac muscle and smooth muscle cells from a single cell. The team confirmed that finding by isolating cells in which both genes were active and demonstrating their ability to form both heart muscle types in living animals.

"In summary, we have established the existence of a common myogenic precursor cell that gives rise to both myocardial and smooth muscle lineages," Orkin wrote. "This bipotential progenitor cell makes a lineage choice decision at a single-cell level. These findings reveal a hierarchy for myogenic differentiation in vivo and suggest a new developmental paradigm for cardiogenesis where a single multipotent progenitor cell gives rise to cells of diverse lineages within the heart."

While the Isl1+ cells studied by Chien may give rise to the c-kit+Nkx2.5+ cells examined by Orkin, the precise relationship between the progenitor cells investigated in the two studies is an open question requiring further study, the researchers noted.

"It's unknown what the relationship between these cells is, if any. One may be the predecessor of the other, or they might be quite separate," Orkin said, noting that the cells under study in the two papers appear to be derived from two separate pools, or fields, of heart progenitors. The primary and secondary heart fields are thought from previous studies to generate structures of the left and right side of the heart, respectively.

The discovery of cardiovascular-specific progenitors may hold promise for cardiac stem cell therapies, the researchers said.

"Embryonic stem cells are difficult to use for heart regeneration because of the danger of teratomas," Chien said. Teratomas are cancers that result from the uncontrolled growth of embryonic stem cells. "If we can get around that threat by cloning master cardiovascular stem cells, that would be a major advance."

"Regenerative stem cell therapies for heart disease will require an understanding of and an ability to manipulate the molecular mechanisms that govern the fates, differentiation, and morphogenesis of the myriad cell types that comprise the heart," wrote Daniel Garry and Eric Olson in a minireview that will accompany the new studies in Cell's Dec. 15 issue. These studies offer a "step toward this goal" by providing "evidence for common multipotential progenitors of the three major cell types of the heart."
-end-
Moretti et al.

The researchers Alessandra Moretti, Jason T. Lam, Karl-Ludwig Laugwitz, of Massachusetts General Hospital in Boston and Technische Universität München in München; Leslie Caron, Atsushi Nakano, Yibing Qyang, Lei Bu, Mika Sasaki, and Silvia Martin-Puig of Massachusetts General Hospital in Boston; Alexandra Bernshausen of Technische Universität München in München; Yinhong Chen of University of California, San Diego in La Jolla, presently at Geron Corporation in Menlo Park; Yunfu Sun of University of California, San Diego in La Jolla; Sylvia Evans of University of California, San Diego, School of Medicine in La Jolla; Kenneth R. Chien of Massachusetts General Hospital and Harvard Medical School in Boston, and the Harvard Stem Cell Institute in Cambridge.

These studies were performed onsite in the Chien laboratory at MGH and the Laugwitz laboratory at the Technical University Munich. This work was supported by unrestricted funds from MGH and the Cardiovascular Disease Program of the Harvard Stem Cell Institute (K.R.C.), a Marie Curie Excellence Team Grant from the Research Commission of the European Union (EXT - 02380) (K.L.L.); Medical Research Funds of the TU Munich (K.L.L.); the National Heart, Lung, and Blood Institute (K.R.C., Y.Q., S.E.); the French Medical Research Foundation (L.C.); and the Jean Le Ducq Foundation.

Wu et al.

The researchers include Sean M. Wu and Susan M. Cibulsky of Massachusetts General Hospital in Boston; Yuko Fujiwara and David E. Clapham of Howard Hughes Medical Institute and Massachusetts General Hospital in Boston; Ching-ling Lien of University of Southern California in Los Angeles; Thomas M. Schultheiss of Beth Israel-Deaconess Medical Center in Boston; Stuart H. Orkin of Howard Hughes Medical Institute, Harvard Medical School, and Children's Hospital in Boston, and Harvard Stem Cell Institute in Cambridge.

Financial support was provided by NIH (T32 HL002807, K08 HL081086), the ACCF/Pfizer Postdoctoral Fellowship in Cardiovascular Medicine, and the de Gunzburg Family Foundation (to S.M.W.), and by the Howard Hughes Medical Institute (to D.E.C. and S.H.O.). None of the authors have a conflict of interest related to this work.

Moretti et al.: "Multipotent Embryonic Isl1+ Progenitor Cells Lead to Cardiac, Smooth Muscle, and Endothelial Cell Diversification." Publishing online 22 November; Scheduled for the 15 December 2006 issue of Cell.

Wu et al.: "Developmental Origin of a Bipotential Myocardial and Smooth Muscle Cell Precursor in the Mammalian Heart." Publishing online 22 November; Scheduled for the 15 December 2006 issue of Cell.

Related Article by Kattman et al.: "Multipotent Flk-1+ Cardiovascular Progenitor Cells Give Rise to the Cardiomyocyte, Endothelial, and Vascular Smooth Muscle Lineages."

Cell Press

Related Stem Cells Articles from Brightsurf:

SUTD researchers create heart cells from stem cells using 3D printing
SUTD researchers 3D printed a micro-scaled physical device to demonstrate a new level of control in the directed differentiation of stem cells, enhancing the production of cardiomyocytes.

More selective elimination of leukemia stem cells and blood stem cells
Hematopoietic stem cells from a healthy donor can help patients suffering from acute leukemia.

Computer simulations visualize how DNA is recognized to convert cells into stem cells
Researchers of the Hubrecht Institute (KNAW - The Netherlands) and the Max Planck Institute in Münster (Germany) have revealed how an essential protein helps to activate genomic DNA during the conversion of regular adult human cells into stem cells.

First events in stem cells becoming specialized cells needed for organ development
Cell biologists at the University of Toronto shed light on the very first step stem cells go through to turn into the specialized cells that make up organs.

Surprising research result: All immature cells can develop into stem cells
New sensational study conducted at the University of Copenhagen disproves traditional knowledge of stem cell development.

The development of brain stem cells into new nerve cells and why this can lead to cancer
Stem cells are true Jacks-of-all-trades of our bodies, as they can turn into the many different cell types of all organs.

Healthy blood stem cells have as many DNA mutations as leukemic cells
Researchers from the Princess Máxima Center for Pediatric Oncology have shown that the number of mutations in healthy and leukemic blood stem cells does not differ.

New method grows brain cells from stem cells quickly and efficiently
Researchers at Lund University in Sweden have developed a faster method to generate functional brain cells, called astrocytes, from embryonic stem cells.

NUS researchers confine mature cells to turn them into stem cells
Recent research led by Professor G.V. Shivashankar of the Mechanobiology Institute at the National University of Singapore and the FIRC Institute of Molecular Oncology in Italy, has revealed that mature cells can be reprogrammed into re-deployable stem cells without direct genetic modification -- by confining them to a defined geometric space for an extended period of time.

Researchers develop a new method for turning skin cells into pluripotent stem cells
Researchers at the University of Helsinki, Finland, and Karolinska Institutet, Sweden, have for the first time succeeded in converting human skin cells into pluripotent stem cells by activating the cell's own genes.

Read More: Stem Cells News and Stem Cells Current Events
Brightsurf.com is a participant in the Amazon Services LLC Associates Program, an affiliate advertising program designed to provide a means for sites to earn advertising fees by advertising and linking to Amazon.com.