Christian Danielsson

Islet-1 cells are cardiac progenitors present during the entire lifespan: from the embryonic stage to adulthood.

The aim of this study was to longitudinally characterize the distribution of cells actively expressing the progenitor transcription factor islet-1 (Isl1+) during the embryonic life, the postnatal period, and adulthood. In this study, we have used direct immunohistochemical staining toward the protein Isl1 in a longitudinal rat model. Cells actively expressing Isl1 were traced in embryos from gestational day (GD) 11 until adulthood. In early cardiac development (GD 11), the Isl1+ progenitors were located in a greater abundance in the paracardiac regions, areas suggested to be the second heart field. To a lesser extent, Isl1+ cells were present within the bulbotruncal region and the truncus arteriosus. During the following days until GD 15, the Isl1+ cells were mainly observed at the proximal outflow tract (OFT) and at the inflow area of the right atrium. No Isl1+ cells were detected in the left ventricle. Compared with GD 11, more Isl1+ cells seemed to co-express cardiomyocyte markers and a minority of the Isl1+ cells was undifferentiated. Unexpectedly, only few undifferentiated Isl1+ cells were Ki67+ while a lot of TnT+ cardiomyocytes were proliferating in the ventricles. After birth, immature Isl1+ cells were still present in the OFT where they resided until adulthood. Our data suggest that during embryogenesis, Isl1+ cells migrate from extracardiac regions into the proximal part of the heart, proliferating and giving rise to cardioblasts. Unexpectedly, only a minority of the Isl1+ cells while a majority of ventricular cardiomyocytes were proliferating. The Isl1+ cell pool persists into adulthood, which might open up new strategies to repair damaged myocardium.

Costimulation Blockade Induces Tolerance to HESC Transplanted to the Testis and Induces Regulatory T‐Cells to HESC Transplanted into the Heart

In order to study the ability of costimulation blockade to induce tolerance to human embryonic stem cells (HESC), severe combined immunodeficient (SCID), and immunocompetent C57BL/6 mice treated with costimulation blockade received intratesticular and intramyocardial HESC transplants. All SCID mice with intratesticular HESC transplants developed teratoma. When SCID mice were transplanted intramyocardially, only two of five mice developed teratoma‐like tumors. C57BL/6 mice transplanted intratesticularly and treated with costimulation blockade all developed teratoma and were surrounded by CD4+CD25+Foxp3+ T‐cells, while isotype control treated recipients rejected their grafts. Most C57BL/6 mice transplanted intramyocardially and treated with costimulation blockade demonstrated lymphocytic infiltrates 1 month after transplantation, whereas one maintained its graft. Isolation of regulatory T‐cells from intramyocardial transplanted recipients treated with costimulation blockade demonstrated specificity toward undifferentiated HESC and down‐regulated naive T‐cell activation toward HESC. These results demonstrate that costimulation blockade is sufficiently robust to induce tolerance to HESC in the immune‐privileged environment of the testis. HESC specific regulatory T‐cells developed to HESC transplanted to the heart and the success of transplantation was similar to that seen in SCID mice.

Exploration of human, rat, and rabbit embryonic cardiomyocytes suggests K-channel block as a common teratogenic mechanism

AIMS Several drugs blocking the rapidly activating potassium (K(r)) channel cause malformations (including cardiac defects) and embryonic death in animal teratology studies. In humans, these drugs have an established risk for acquired long-QT syndrome and arrhythmia. Recently, associations between cardiac defects and spontaneous abortions have been reported for drugs widely used in pregnancy (e.g. antidepressants), with long-QT syndrome risk. To investigate whether a common embryonic adverse-effect mechanism exists in the human, rat, and rabbit embryos, we made a comparative study of embryonic cardiomyocytes from all three species. METHODS AND RESULTS Patch-clamp and quantitative-mRNA measurements of K(r) and slowly activating K (K(s)) channels were performed on human, rat, and rabbit primary cardiomyocytes and cardiac samples from different embryo-foetal stages. The K(r) channel was present when the heart started to beat in all species, but was, in contrast to human and rabbit, lost in rats in late organogenesis. The specific K(r)-channel blocker E-4031 prolonged the action potential in a species- and development-dependent fashion, consistent with the observed K(r)-channel expression pattern and reported sensitive periods of developmental toxicity. E-4031 also increased the QT interval and induced 2:1 atrio-ventricular block in multi-electrode array electrographic recordings of rat embryos. The K(s) channel was expressed in human and rat throughout the embryo-foetal period but not in rabbit. CONCLUSION This first comparison of mRNA expression, potassium currents, and action-potential characteristics, with and without a specific K(r)-channel blocker in human, rat, and rabbit embryos provides evidence of K(r)-channel inhibition as a common mechanism for embryonic malformations and death.

New Proposals for Testing Drugs with IKr-Blocking Activity to Determine Their Teratogenic Potential

Drugs blocking the potassium current IKr, either as an intended pharmacologic effect (eg antiarrhythmics dofetilide and almokalant) or as an unwanted side-effect (eg antihistamine astemizole, propulsive drug cisapride, antidepressive drugs and macrolide antibiotics) are potential human teratogens. It is the contention of this paper that the existing repeat dose regimen used in teratology studies to fulfil regulatory requirements, does not properly identify the teratogenic risk of these drugs. Results from conventional studies for dofetilide and almokalant showed high rates of postimplantation embryonic death with few malformed fetuses. For astemizole and cisapride only embryonic death was seen. These latter results were not considered important because they occurred either in the presence of maternal toxicity and/or at high doses. Subsequent studies have shown that IKr-blockers are highly teratogenic when administered on single gestational days (GD) during a sensitive period of rat pregnancy (GD 10-14) when they induce a high incidence of stage-specific malformations. This teratogenic activity of astemizole and cisapride was missed in the original teratology studies. Mechanistically IKr-blockers cause bradycardia and arrhythmia of the embryonic heart and while an embryo may be able to survive a single day exposure to a teratogenic dose, repeat dosing often leads to death of the embryo. With this review we suggest that new drugs identified at the preclinical stage of development as having IKr-blocking properties, should undergo more comprehensive teratology testing including single GD dosing and studies using embryo culture. This would further help identify and characterise their teratogenic potential.

Early first trimester human embryonic cardiac Islet-1 progenitor cells and cardiomyocytes: Immunohistochemical and electrophysiological characterization.

The aims of this study were to systematically characterize the distribution, proliferation, and differentiation of Islet-1(+)(Isl1(+)) progenitor cells in the early first trimester human embryonic heart during which period most of the organogenesis takes place. In hearts of gestational week 5 to 10 Isl1(+)cells were identified and mainly clustered in the outflow tract and to a lesser extent in the atria and in the right ventricle. Some of the clusters were also troponin T(+). Unexpectedly a only few Isl1(+)cells were Ki67(+)while in the ventricles a majority of Isl1(-)troponinT(+)cells were Ki67(+). Cultures derived from the digested embryonic heart developed into spontaneously beating cardiospheres. At harvest cells in these cardiospheres showed frequent expression of troponin T(+)and Nkx2.5(+), while Isl1 was expressed only in scattered cells. Only a minority of the cultured cells expressed Ki67. The cardiospheres could be frozen, thawed, and recultured to beating cardiospheres. In a multielectrode array system, the beating cardiospheres were responsive to adrenergic stimulation and exhibited rate-dependent action potential duration. In conclusion, the early first trimester human embryonic heart expresses clusters of Isl1(+)cells, some of which differentiate into cardiomyocytes. Unexpectedly, only a minority of the Isl1(+)cells, while a majority of ventricular cardiomyocytes, were proliferating. Spontaneously beating cardiospheres could be derived from the human embryonic heart and these cardiospheres showed functional frequency control.

Improved methodology for identifying the teratogenic potential in early drug development of hERG channel blocking drugs.

Drugs blocking the potassium current IKr of the heart (via hERG channel-inhibition) have the potential to cause hypoxia-related teratogenic effects. However, this activity may be missed in conventional teratology studies because repeat dosing may cause resorptions. The aim of the present study was to investigate an alternative protocol to reveal the teratogenic potential of IKr-blocking drugs. The IKr blocker astemizole, given as a single dose (80 mg/kg) on gestation day (GD) 13 to pregnant rats caused digital defects. In whole rat embryo culture (2h) on GD 13, astemizole caused a decrease in embryonic heart rate at 20 nM, and arrhythmias at 200-400 nM. Cetirizine, without IKr-blocking properties, did not affect the rat embryonic heart in vitro. The present study shows that single dose testing on sensitive days of development, together with whole embryo culture, can be a useful methodology to better characterize the teratogenic potential of IKr-blocking drugs.

Erythropoietin has an antiapoptotic effect after myocardial infarction and stimulates in vitro aortic ring sprouting.

Aims were to explore if darbepoietin-alpha in mouse can induce angiogenesis and if moderate doses after myocardial infarction stimulates periinfarct capillary and arteriolar densities, cell proliferation, and apoptosis. Myocardial infarction was induced by ligation of LAD. Mouse aortic rings (0.8mm) were cultured in matrigel and the angiogenic sprouting was studied after addition of darbepoietin-alpha with and without VEGF-165. After 12 days the hemoglobin concentration was 25% higher in the darbepoietin-alpha treated mice than in the control group. No difference in capillary densities in the periinfarct or noninfarcted areas was seen with darbepoietin-alpha. Cell proliferation was about 10 times higher in the periinfarct area than in the noninfarcted wall. Darbepoietin-alpha treatment led to a decrease of cell proliferation (BrdU, (p<0.02)) and apoptosis (TUNEL, p<0.005) with about 30% in the periinfarct area. Darbepoietin-alpha and VEGF-165 both independently induced sprouting from aortic rings. The results suggest that darbepoietin-alpha can induce angiogenesis but that moderate doses after myocardial infarction are not angiogenic but antiapoptotic.

Isolation and Characterization of the SSEA-1+ Progenitor Cells from the Human Embryonic Heart

Background: The optimal stem cell source for regenerative therapy of the failing heart has not been settled. Embryonic stem cells, bone marrow derived cells, skeletal myoblasts, as well as cells derived from adult cardiac biopsies have been explored. Here we investigated the option to generate heart progenitor cells from the early human embryonic heart (hEHPCs) for the treatment of acute myocardial infarction. Methods: Two hearts (8 and 8.5 gestational weeks) from human abortion material were used for the clonal expansion of hEHPCs after stage specific embryonic antigen 1 (SSEA-1) enrichment by magnetic beads isolation. GFP-transduced hEHPCs- were transplanted into 18 SCID mice intramyocardially after induction of myocardial infarction. Hearts were harvested every 72 hours. Results: In this study we succeeded to isolate clones of hEHPCs with similar characteristics twice from two different early human embryonic hearts (8 and 8.5 gestational weeks) based on SSEA-1, a multipotent stem cell marker. Isolated clones were found to be positive for the multipotent stem cell marker (c-kit), the cardiac progenitors transcription factors GATA4, NKX2.5, TBX5 as well as the endothelial progenitors markers (CD133, CD34 and KDR). After transplantation into the peri-infarcted region they survived up to 12 days, and formed tubule-like structures in the mouse heart. Conclusions: These data demonstrate that the SSEA-1+ enriched cell population provides a potential basis to find the optimal cardiac progenitor cell population.