Angiotensin II and tumour necrosis factor α as mediators of ATP-dependent potassium channel remodelling in post-infarction heart failure

Aims Angiotensin II (Ang II) and tumour necrosis factor α (TNFα) are involved in the progression from compensated hypertrophy to heart failure. Here, we test their role in the remodelling of ATP-dependent potassium channel (KATP) in heart failure, conferring increased metabolic and diazoxide sensitivity. Methods and results We observed increased expression of both angiotensinogen and TNFα in the failing rat myocardium, with a regional gradient matching that of the KATP subunit Kir6.1 expression. Both angiotensinogen and TNFα expression correlated positively with Kir6.1 and negatively with Kir6.2 expression across the post-infarction myocardium. To further identify a causal relationship, cardiomyocytes isolated from normal rat hearts were exposed in vitro to Ang II or TNFα. We observed increased Kir6.1 and SUR subunit and reduced Kir6.2 subunit mRNA expression in cardiomyocytes cultured with Ang II or TNFα, similar to what was observed in failing hearts. In patch-clamp experiments, cardiomyocytes cultured with Ang II or TNFα exhibited responsiveness to diazoxide, in terms of both KATP current and action potential shortening. This was not observed in untreated cardiomyocytes and resembles the diazoxide sensitivity of failing cardiomyocytes that also overexpress Kir6.1. Ang II exerted its effect through induction of TNFα expression, because TNFα-neutralizing antibody abolished the effect of Ang II, and in failing hearts, regional expression of angiotensinogen matched TNFα expression. Finally, Ang II and TNFα regulated KATP subunit expression, possibly through differential expression of Forkhead box transcription factors. Conclusion This study identifies Ang II and TNFα as mediators of the remodelling of KATP channels in heart failur

Angiotensin II and tumour necrosis factor alpha as mediators of ATP-dependent potassium channel remodelling in post-infarction heart failure

AIMS: Angiotensin II (Ang II) and tumour necrosis factor alpha (TNFalpha) are involved in the progression from compensated hypertrophy to heart failure. Here, we test their role in the remodelling of ATP-dependent potassium channel (K(ATP)) in heart failure, conferring increased metabolic and diazoxide sensitivity. METHODS AND RESULTS: We observed increased expression of both angiotensinogen and TNFalpha in the failing rat myocardium, with a regional gradient matching that of the K(ATP) subunit Kir6.1 expression. Both angiotensinogen and TNFalpha expression correlated positively with Kir6.1 and negatively with Kir6.2 expression across the post-infarction myocardium. To further identify a causal relationship, cardiomyocytes isolated from normal rat hearts were exposed in vitro to Ang II or TNFalpha. We observed increased Kir6.1 and SUR subunit and reduced Kir6.2 subunit mRNA expression in cardiomyocytes cultured with Ang II or TNFalpha, similar to what was observed in failing hearts. In patch-clamp experiments, cardiomyocytes cultured with Ang II or TNFalpha exhibited responsiveness to diazoxide, in terms of both K(ATP) current and action potential shortening. This was not observed in untreated cardiomyocytes and resembles the diazoxide sensitivity of failing cardiomyocytes that also overexpress Kir6.1. Ang II exerted its effect through induction of TNFalpha expression, because TNFalpha-neutralizing antibody abolished the effect of Ang II, and in failing hearts, regional expression of angiotensinogen matched TNFalpha expression. Finally, Ang II and TNFalpha regulated K(ATP) subunit expression, possibly through differential expression of Forkhead box transcription factors. CONCLUSION: This study identifies Ang II and TNFalpha as mediators of the remodelling of K(ATP) channels in heart failure

Forkhead transcription factors coordinate expression of myocardial KATP channel subunits and energy metabolism

Coordinate adaptation of myocyte metabolism and function is fundamental to survival of the stressed heart, but the mechanisms for this coordination remain unclear. Bioinformatics led us to discover that Foxs are key transcription factors involved. We performed experiments on the mouse atrial cell line HL-1, neonate rat heart myocytes, and an adult rat model of myocardial infarction. In electrophoretic mobility-shift assays, FoxO1 binds to the FoxO concensus site of the KATP channel subunit KIR6.1 promoter. In primary atrial culture, targeting FoxO1 and FoxO3 with siRNA specifically reduces mRNA expression of FoxO1 and -O3 and KIR6.1. Western blots, confocal immunofluorescence, and quantitative RT-PCR was applied for measuring expression of 10 Fox, 6 KATP channel subunits, and 12 metabolic genes. FoxF2, -O1, and -O3 strongly associate with expression of KATP channel subunits (in particular, KIR6.1, SUR1A and SUR2B) in different heart tissues and in the periinfarct zone of the left ventricle. Patch-clamp recordings demonstrate that molecular plasticity of these channels is matched by pharmacological plasticity and increased sensitivity to a metabolic challenge mimicked by the protonophore CCCP. A balance of FoxF2 and FoxO also regulates expression of at least 9 metabolic genes involved in setting the balance of glycolysis and beta-oxidation. Bioinformatics shows that the transcriptional mechanisms are highly conserved among chicken, mouse, rat, and human, and Fox are intimately linked to other metabolic sensors. Thus, FoxF2 and -O are key transcription factors coordinating expression of KATP channels and energy metabolism