Project description: Not available

Project description: Not available

Project description: Not available

Project description: Not available

Project description: Not available

Project description:Sustained atrial tachycardia leads to multiple molecular and cellular effects collectively defined as atrial tachycardia remodeling (ATR). ATR is thought to play a major role in the self-perpetuating nature of atrial fibrillation (AF) and has been a subject of intense research in large mammalian models of AF. Recently, rodents are increasingly used to gain insight on the pathophysiology AF. However, little is known regarding the effects of rapid pacing on the atria of rats and mice mainly due to technical challenges in electrophysiological studies of unanesthetized rodents. Using an implantable device for electrophysiological studies in unanesthetized rodents we examine, on a daily basis, the effects of continuous rapid atrial pacing (RAP) for at least 4 consecutive days on the developed AF substrate of Sprague-Dawley rats and C57BL6 mice. AF induction protocol consisted 10 aggressive bursts (20 seconds, double diastolic threshold, 10 ms cycle length [CL]). This protocol failed to induce AF at baseline in both species, but repeatedly induced AF episodes in rats following 2 days of sustained RAP. Microarray study of left atrial tissue from rats exposed for 2 days to RAP (70 ms CL) vs control pacing (140 ms CL) identified 304 differentially expressed genes (155 upregulated and 149 downregulated). Real-time qt-PCR confirmed the validity of the microarray. Enrichment analysis and comparison with a dataset of atrial tissue from AF patients revealed indications of increased carbohydrate metabolism, and changes in pathways that are thought to have critical role in human AF including TGF-beta and IL-6 signaling. Among 19 commonly affected genes in comparison with human AF, downregulation of FOXP1 and upregulation of the KCNK2 gene encoding the Kir2.1 potassium channel were conspicuous finding suggesting NFAT activation. Further results in line with NFAT activation included reduced expression of MIR-26, MIR-101, which were linked to upregulation of the KCNK2 in human AF. Our results demonstrate electrophysiological evidence for AF promoting effects of RAP in rats and some important molecular similarities between the effects of RAP in large and small mammalian models. The effects of atrial tachypacing are well documented in large mammals but very little is know regarding the effects of tacypacing on the rodent atria.

Project description:Introduction: Atrial fibrillation (AF) is the most common arrhythmia and affects around 1% of the population with increasing incidence and substantial morbidity. Functional effects of genetic variants associated with AF should help to identify targets involved in AF initiation and/or subsequent remodeling. Gene variants next to the gene of the transcription factor PITX2 (paired-like homeodomain transcription factor 2) showed the strongest association with AF. A significant number of AF patients showed reduced PITX2 levels in the left atrium. Mouse models have been used to study functional aspects of PITX2 gene deletion (“knock out”), but there are substantial differences in atrial electrophysiology between mouse and human . HiPSC-CM should be able to bridge the gap, provided the cells reproduce typical characteristics of human atrium. Methods: PITX2 knock out samples from a control cell line of human induced pluripotent stem cells (hiPSC) were obtained. Differentiation and generation of Atrial-like engineered heart tissue (aEHT) was performed. RNA-sequencing (RNA-Seq), Quantitative Real-time PCR (RT-qPCR), Protein analysis by Western Blot, Contraction and force analysis, action potential measurements, Calcium current measurements and differential gene expression analysis were run on the samples. Results: Effective knock out of PITX2 was confirmed by mRNA sequencing and WB. It was shown that PITX2 deficiency reduces contraction force. PITX2 deficiency induces action potential triangulation with more negative maximum diastolic potential. Activation of muscarinic receptors shortens APD in both PITX2 knockout and controls but hyperpolarization is lost in PITX2 knock out. It was shown that Ca2+ current density is smaller in PITX2 knock out than controls. We found that more negative MDP in PITX2 knock out is not associated with higher IK1. Conclusion: We improved atrial differentiation, coming very close to human atrial electrophysiology. We demonstrate that PITX2 deficiency induces key characteristics known from persistent AF.

Project description: Not available

Project description: Not available

Project description: Not available