The homeodomain transcription factor Irx5 establishes the mouse cardiac ventricular repolarization gradient - PubMed (original) (raw)

. 2005 Oct 21;123(2):347-58.

doi: 10.1016/j.cell.2005.08.004.

Eric P Arruda, Pooja Agarwal, Kyoung-Han Kim, Yonghong Zhu, Wei Zhu, Melanie Lebel, Chi Wa Cheng, Chong Y Park, Stephanie A Pierce, Alejandra Guerchicoff, Guido D Pollevick, Toby Y Chan, M Golam Kabir, Shuk Han Cheng, Mansoor Husain, Charles Antzelevitch, Deepak Srivastava, Gil J Gross, Chi-chung Hui, Peter H Backx, Benoit G Bruneau

Affiliations

The homeodomain transcription factor Irx5 establishes the mouse cardiac ventricular repolarization gradient

Danny L Costantini et al. Cell. 2005.

Abstract

Rhythmic cardiac contractions depend on the organized propagation of depolarizing and repolarizing wavefronts. Repolarization is spatially heterogeneous and depends largely on gradients of potassium currents. Gradient disruption in heart disease may underlie susceptibility to fatal arrhythmias, but it is not known how this gradient is established. We show that, in mice lacking the homeodomain transcription factor Irx5, the cardiac repolarization gradient is abolished due to increased Kv4.2 potassium-channel expression in endocardial myocardium, resulting in a selective increase of the major cardiac repolarization current, I(to,f), and increased susceptibility to arrhythmias. Myocardial Irx5 is expressed in a gradient opposite that of Kv4.2, and Irx5 represses Kv4.2 expression by recruiting mBop, a cardiac transcriptional repressor. Thus, an Irx5 repressor gradient negatively regulates potassium-channel-gene expression in the heart, forming an inverse I(to,f) gradient that ensures coordinated cardiac repolarization while also preventing arrhythmias.

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Figures

Figure 1

Figure 1. Repolarization Gradients in the Mammalian Heart

The gradient of density of _I_to,f and Kv4.2 protein is shown as red dots on a diagram of the heart. Examples of outward currents and action potential resulting from the high _I_to,f/Kv4.2 in epicardial myocardium and low _I_to,f/Kv4.2 in endocardial and septal myocardium are shown. See text for details.

Figure 2

Figure 2. Absent T Wave and Inducible Arrhythmias in _Irx5_−/− Mice

(A) Representative ECGs in the lead II configuration recorded from awake, free-moving mice with the use of telemetric monitoring. Wild-type mice (+/+) show pronounced downward T wave deflections (arrows). No T waves are evident in ECG recordings of _Irx5_−/− mice (−/−). (B) Quantitation of T wave amplitude (mean ± SEM). n = 6–8; *p < 0.01. (C and D) Representative intracardiac ECG (IECG, red) and surface ECG (SECG, black) in the lead II configuration obtained from wild-type (Irx5+/+) and _Irx5_−/− mice. (C) Programmed ventricular stimulation at the right ventricular apex using two extra stimuli (“S2S3”) induced episodes of ventricular tachycardia (VT) in _Irx5_−/− mice, whereas no VTs could be induced in wild-type animals. (D) Rapid overdrive pacing in _Irx5_−/− mice also induced VTs of long duration.

Figure 3

Figure 3. Shortened Endocardial Action Potentials in _Irx5_−/− Cardiomyocytes

(A) Representative action-potential traces from Irx5+/+ and _Irx5_−/−cardiomyocytes from epicardium and endocardium. _Irx5_−/− endocardial cardiomyocytes demonstrate a shortening of the action potential (arrows). (B) Mean action-potential durations (APD) measured at 25%, 50%, and 90% repolarization following complete depolarization. n = 6–14, *p < 0.05. Scale bars: 20 mV, 25 ms. Data are mean ± SEM.

Figure 4

Figure 4. The Transmural Gradient of _I_to Is Eliminated in _Irx5_−/− Cardiomyocytes

(A) Whole-cell outward K+ currents were recorded from wild-type (+/+) and _Irx5_−/− (−/−) cardiomyocytes from epicardial (LV apex) and endocardial (septum) regions of the heart. (B) Mean ± SEM normalized peak _I_to amplitudes are plotted as a function of test pulse (top, epicardium; bottom, endocardium). (C) Normalized current densities (pA/pF) for _I_to, _I_k,slow1, _I_k,slow2, and _I_ss measured at +60 mV. (D) Maximum current-conductance values for _I_to (Gmax). (E) Normalized current densities (pA/pF) for _I_to,f and _I_to,s measured at +60 mV. (F) Normalized current densities (pA/pF) for _I_to measured in myocytes isolated from LV free wall epicardium or endocardium at +60 mV. For all, n = 6–14, *p < 0.05. Scale bars: 5 nA, 500 ms. Data are mean ± SEM.

Figure 5

Figure 5. Kv4.2 Expression Is Increased in the Endocardium of _Irx5_−/− Mice

(A) Representative Western blots, using specific anti-Kv4.2, anti-Kv4.3, and anti-Kv1.5 antibodies. (B) Quantitation of Western blot analyses shows increased Kv4.2 protein in _Irx5_−/− endocardial myocardium. (C) Relative expression of Kcnd2, Kcnd3, Kcna5, and Kcnip2 in the hearts of wild-type and _Irx5_−/− mice assessed by quantitative real-time RT-PCR. mRNA levels (mean ± SEM) are relative to average wild-type epicardial values; n = 6–8, *p < 0.05 Irx5+/+ endocardial myocardium (Endo) compared with Irx5+/+ epicardial myocardium (Epi), **p < 0.05 _Irx5_−/− Endo compared with Irx5+/+ Endo. Data are mean ± SEM.

Figure 6

Figure 6. Inverse Gradients of Irx5 and Kv4.2 in the Mouse Heart

(A–F) Immunohistochemistry for Irx5 at E14.5 (A and B) and E16.5 (D and E). Regions in (A) and (D) are magnified in (B) and (E). Only background staining is apparent in _Irx5_−/−embryos (C and F). lv, left ventricle; rv, right ventricle. (G and H) Irx5 (G) and Kv4.2 (H) expression in adult myocardium. (I) Images in (G) and (H) were pseudocolored green and red, respectively, and digitally merged. (J) Western blot showing Irx5 expression in nuclear extract from epicardial myocardium (lane 1), endocardial myocardium (lane 2), isolated myocytes from epicardial myocardium (lane 3), isolated myocytes from endocardial myocardium (lane 4), isolated neonatal myocytes (lane 5), isolated myocytes from _Irx5_−/− epicardial myocardium (lane 6), and isolated myocytes from _Irx5_−/− endocardial myocardium (lane 7). GAPDH is shown as loading control. (K) Quantitation of Irx5 Western blot; n = 3, *p < 0.05. (L) Relative expression of Irx5 mRNA in dog heart; n = 5, *p < 0.05. Data are mean ± SEM. (M) Immunoreactivity of Irx5 and Kv4.2 in the ventricles of adult wild-type (+/+) and _Irx5_−/−mice (−/−).

Figure 7

Figure 7. Irx5 Directly Represses the Kcnd2 Promoter

(A) Kcnd2 −1094–+592-luciferase and Kcnd2 −432–+592-luciferase (but not Kcnd2 −3162–+592-luciferase) are strongly activated in neonatal cardiac myocytes. Addition of an Irx5 expression construct (Irx5) reduces the activity of Kcnd2 reporters. For this and all other panels: +, 100 ng; ++, 250 ng; +++, 500 ng; ++++, 1000 ng Irx5 expression construct. (B) Irx5 activates _Kcnd2_-luciferase in COS cells. (C) mBop interacts with Irx4 and Irx5. Immunoprecipitation using anti-HA antibodies followed by immunoblotting against FLAG shows that mBop (arrow) can interact with Irx4 and Irx5. (D) mBop prevents activation of Kcnd2 −1094–+592-luciferase by Irx5. Similar results were obtained with Kcnd2 −432–+592-luciferase. (E) Histone deacetylase inhibition by trichostatin A (TSA) relieves the inhibition of Irx5 activity by mBop. In (D) and (E) for mBop: +, 500 ng; ++, 1000 ng expression constructs. (F) Diagram of Irx5 proteins used in (G) and (H). HD, homeodomain; Iro, Iro box. (G) Irx5ΔHD or Irx5ΔC2 no longer activates transcription, while Irx5ΔC1 activates but is not repressed by mBop. (H) Coimmunoprecipitations show that mBop cannot interact with Irx5ΔC1 or Irx5ΔC2. (I) mBop is required for Irx5-mediated repression in cardiac myocytes. siRNAs against mBop (+, 25 ng; ++, 50 ng) reduced expression of Kcnd2 −432–+592-luciferase and prevented Irx5-mediated repression. Data are mean ± SEM. (J) Model for the role of Irx5; see text for details.

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