The mammalian heart has a very limited regenerative capacity and, hence, heals by scar formation. Recent reports suggest that haematopoietic stem cells can transdifferentiate into unexpected phenotypes such as skeletal muscle, hepatocytes, epithelial cells, neurons, endothelial cells and cardiomyocytes, in response to tissue injury or placement in a new environment. Furthermore, transplanted human hearts contain myocytes derived from extra-cardiac progenitor cells, which may have originated from bone marrow. Although most studies suggest that transdifferentiation is extremely rare under physiological conditions, extensive regeneration of myocardial infarcts was reported recently after direct stem cell injection, prompting several clinical trials. Here, we used both cardiomyocyte-restricted and ubiquitously expressed reporter transgenes to track the fate of haematopoietic stem cells after 145 transplants into normal and injured adult mouse hearts. No transdifferentiation into cardiomyocytes was detectable when using these genetic techniques to follow cell fate, and stem-cell-engrafted hearts showed no overt increase in cardiomyocytes compared to sham-engrafted hearts. These results indicate that haematopoietic stem cells do not readily acquire a cardiac phenotype, and raise a cautionary note for clinical studies of infarct repair.
Abstract-Studies on patients and large animal models suggest the importance of atrial fibrosis in the development of atrial fibrillation (AF). To investigate whether increased fibrosis is sufficient to produce a substrate for AF, we have studied cardiac electrophysiology (EP) and inducibility of atrial arrhythmias in MHC-TGFcys 33 ser transgenic mice (Tx), which have increased fibrosis in the atrium but not in the ventricles. In anesthetized mice, wild-type (Wt) and Tx did not show significant differences in surface ECG parameters. With transesophageal atrial pacing, no significant differences were observed in EP parameters, except for a significant decrease in corrected sinus node recovery time in Tx mice. Burst pacing induced AF in 14 of 29 Tx mice, whereas AF was not induced in Wt littermates (PϽ0.01). In Langendorff perfused hearts, atrial conduction was studied using a 16-electrode array. Epicardial conduction velocity was significantly decreased in the Tx RA compared with the Wt RA. In the Tx LA, conduction velocity was not significantly different from Wt, but conduction was more heterogeneous. Action potential characteristics recorded with intracellular microelectrodes did not reveal differences between Wt and Tx mice in either atrium. Thus, in this transgenic mouse model, selective atrial fibrosis is sufficient to increase AF inducibility. Key Words: atrial fibrillation Ⅲ fibrosis Ⅲ growth factors A trial fibrillation (AF) is a commonly occurring arrhythmia, present in Ϸ5% of people older than age 65 years. Clinically, increased vulnerability to AF is also associated with underlying heart disease, such as congestive heart failure (CHF) and mitral valve disease. 1 Increased inducibility of AF has been observed in animal models of aging, 2,3 CHF, 4 atrial tachycardia-induced cardiomyopathy, 5,6 and chronic atrial dilatation caused by mitral regurgitation. 7 Theoretical models have implicated atrial interstitial fibrosis as a substrate for AF. 8,9 Atrial interstitial fibrosis increases with age in humans and has been observed in patients with AF 10,11 and in animal models of aging, 2,3 mitral regurgitation, 7 and CHF. 4 With the unknown cause of atrial fibrosis in humans and the presence of compounding factors in animal models, the contribution of atrial fibrosis to AF substrate formation remains unclear. Studies to date have been limited by lack of animal models of selective atrial fibrosis to study the effects of fibrosis without the presence of heart failure or other underlying heart disease.The purpose of this study was to determine the effect of atrial fibrosis on the AF vulnerability. We have studied a transgenic mouse model with cardiac overexpression of a constitutively active form of transforming growth factor (TGF)-1, MHC-TGFcys 33 ser. 12 This model has been previously demonstrated to have elevated TGF-1 activity in the atria and ventricles. Cardiac development and morphology appear normal, except for increased interstitial fibrosis in the atrial myocardium. Ventricular size and histology is no...
Targeted Expression of Cyclin D2 Results in Cardiomyocyte DNA Synthesis and Infarct Regression in Transgenic Mice
Abstract-Restriction point transit and commitment to a new round of cell division is regulated by the activity of cyclin-dependent kinase 4 and its obligate activating partners, the D-type cyclins. In this study, we examined the ability of D-type cyclins to promote cardiomyocyte cell cycle activity. Adult transgenic mice expressing cyclin D1, D2, or D3 under the regulation of the ␣ cardiac myosin heavy chain promoter exhibited high rates of cardiomyocyte DNA synthesis under baseline conditions. Cardiac injury in mice expressing cyclin D1 or D3 resulted in cytoplasmic cyclin D accumulation, with a concomitant reduction in the level of cardiomyocyte DNA synthesis. In contrast, cardiac injury in mice expressing cyclin D2 did not alter subcellular cyclin localization. Consequently, cardiomyocyte cell cycle activity persisted in injured hearts expressing cyclin D2, ultimately resulting in infarct regression. These data suggested that modulation of D-type cyclins could be exploited to promote regenerative growth in injured hearts. Key Words: cardiomyocyte proliferation Ⅲ DNA synthesis Ⅲ heart regeneration C ardiomyocyte death with an ensuing loss of myocardial function is observed in many forms of cardiovascular disease. This progressive decline in cardiac function might be partially abated if the surviving myocardium retained even a limited ability to proliferate. Although it is generally accepted that adult cardiomyocytes retain some capacity to synthesize DNA, there is considerable debate regarding the frequency at which this occurs, and if reinitiation of DNA synthesis necessarily leads to cell division. 1,2 It is nonetheless clear that the intrinsic regenerative capacity of the adult mammalian heart is insufficient to restore cardiac function after significant injury. Consequently, considerable effort has been invested to study cardiomyocyte cell cycle regulation. 3 Cell cycle progression is regulated at multiple checkpoints to ensure that all requisite activities (ie, genome reduplication, DNA repair, and chromosome segregation) are completed before initiation of the next phase of the cell cycle. Checkpoint transit is regulated in part by a family of protein kinases (the cyclin-dependent kinases or CDKs) and their activating partners (the cyclins). For example, the initial commitment to a new round of cell division requires transit through the restriction point. Restriction point transit is regulated by CDK4 and the D-type cyclins. 4,5 CDK4/cyclin D-mediated phosphorylation of members of the RB protein family disrupts RB-E2F binding, thereby permitting E2F-mediated transcription of genes involved in regulating DNA synthesis. 6,7 Given the fundamental importance of restriction point transit in the activation of DNA synthesis and cell cycle progression, we have previously used the mouse ␣ cardiac myosin heavy chain (MHC) promoter to target expression of cyclin D1. 8 Cyclin D1 expression resulted in high rates of cardiomyocyte DNA synthesis in adult transgenic hearts, and was thus sufficient to drive cell cycle ...
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