The histone acetyltransferase MOF overexpression blunts cardiac hypertrophy by targeting ROS in mice

Imbalance between histone acetylation/deacetylation critically participates in the expression of hypertrophic fetal genes and development of cardiac hypertrophy. While histone deacetylases play dual roles in hypertrophy, current evidence reveals that histone acetyltransferase such as p300 and PCAF act as pro-hypertrophic factors. However, it remains elusive whether some histone acetyltransferases can prevent the development of hypertrophy. Males absent on the first (MOF) is a histone acetyltransferase belonging to the MYST (MOZ, Ybf2/Sas3, Sas2 and TIP60) family. Here in this study, we reported that MOF expression was down-regulated in failing human hearts and hypertrophic murine hearts at protein and mRNA levels. To evaluate the roles of MOF in cardiac hypertrophy, we generated cardiac-specific MOF transgenic mice. MOF transgenic mice did not show any differences from their wide-type littermates at baseline. However, cardiac-specific MOF overexpression protected mice from transverse aortic constriction (TAC)-induced cardiac hypertrophy, with reduced radios of heart weight (HW)/body weight (BW), lung weight/BW and HW/tibia length, decreased left ventricular wall thickness and increased fractional shortening. We also observed lower expression of hypertrophic fetal genes in TAC-challenged MOF transgenic mice compared with that of wide-type mice. Mechanically, MOF overexpression increased the expression of Catalase and MnSOD, which blocked TAC-induced ROS and ROS downstream c-Raf-MEK-ERK pathway that promotes hypertrophy. Taken together, our findings identify a novel anti-hypertrophic role of MOF, and MOF is the first reported anti-hypertrophic histone acetyltransferase.     

The atypical Rho GTPase,RhoU, regulates cell-adhesion molecules during cardiac morphogenesis

The vertebrate heart undergoes early complex morphologic events in order to develop key cardiac structures that regulate its overall function (Fahed et al., 2013). Although many genetic factors that participate in patterning the heart have been elucidated (Tu and Chi, 2012), the cellular events that drive cardiac morphogenesis have been less clear. From a chemical genetic screen to identify cellular pathways that control cardiac morphogenesis in zebrafish, we observed that inhibition of the Rho signaling pathways resulted in failure to form the atrioventricular canal and loop the linear heart tube. To identify specific Rho proteins that may regulate this process, we analyzed cardiac expression profiling data and discovered that RhoU was expressed at the atrioventricular canal during the time when it forms. Loss of RhoU function recapitulated the atrioventricular canal and cardiac looping defects observed in the ROCK inhibitor treated zebrafish. Similar to its family member RhoV/Chp (Tay et al., 2010), we discovered that RhoU regulates the cell junctions between cardiomyocytes through the Arhgef7b/Pak kinase pathway in order to guide atrioventricular canal development and cardiac looping. Inhibition of this pathway resulted in similar underlying cardiac defects and conversely, overexpression of a PAK kinase was able to rescue the loss of RhoU cardiac defect. Finally, we found that Wnt signaling, which has been implicated in atrioventricular canal development (Verhoeven et al., 2011), may regulate the expression of RhoU at the atrioventricular canal. Overall, these findings reveal a cardiac developmental pathway involving RhoU/Arhgef7b/Pak signaling, which helps coordinate cell junction formation between atrioventricular cardiomyocytes to promote cell adhesiveness and cell shapes during cardiac morphogenesis. Failure to properly form these cell adhesions during cardiac development may lead to structural heart defects and mechanistically account for the cellular events that occur in certain human congenital heart diseases.     

Proteomic analysis identifies in vivo candidate matrix metalloproteinase‐9 substrates in the left ventricle post‐myocardial infarction

Matrix metalloproteinase‐9 (MMP‐9) deletion has been shown to improve remodeling of the left ventricle post‐myocardial infarction (MI), but the mechanisms to explain this improvement have not been fully elucidated. MMP‐9 has a broad range of in vitro substrates, but relevant in vivo substrates are incompletely defined. Accordingly, we evaluated the infarct regions of wild‐type (wt) and MMP‐9 null (null) mice using a proteomic strategy. Wt and null groups showed similar infarct sizes (48±3 in wt and 45±3% in null), indicating that both groups received an equal injury stimulus. Left ventricle infarct tissue was homogenized and analyzed by 2‐DE and MS. Of 31 spot intensity differences, the intensities of 9 spots were higher and 22 spots were lower in null mice compared to wt (all p<0.05). Several extracellular matrix proteins were identified in these spots by MS, including fibronectin, tenascin‐C, thrombospondin‐1, and laminin. Fibronectin was observed on the gels at a lower than expected molecular weight in the wt group, which suggested substrate cleavage, and the lower molecular weight spot was observed at lower intensity in the MMP‐9 null group, which suggested cleavage by MMP‐9. Immunoblotting confirmed the presence of fibronectin cleavage products in the wt samples and lower levels in the absence of MMP‐9. In conclusion, examining infarct tissue from wt and MMP‐9 null mice by proteomic analysis provides a powerful and unique method to identify in vivo candidate MMP substrates.     

Cardioprotection in ischemia/reperfusion injury: Spotlight on sphingosine-1-phosphate and bradykinin signalling

Complex signal-transduction cascades are known to be involved in regulating cardiomyocyte function, death and survival during acute cardiac ischemia-reperfusion process, but detailed survival signalling pathways are not clear. This review presents and discusses the recent findings bearing upon the evidence on the cardioprotective effect of sphingosine-1-phosphate (S1P) and bradykinin in acute cardiac ischemia-reperfusion and underlying signalling mechanisms, particularly, through activation of P21 activated kinase.     

不同类型慢性心力衰竭患者临床特征及心功能危险因素、预后影响因素分析

摘要 目的：分析不同类型慢性心力衰竭患者临床特征及心功能危险因素、预后影响因素。方法：回顾性分析2020年1月-2022年1月我院收治的慢性心力衰竭患者80例，根据左室射血分数（LVEF）分为A组（n=25，LVEF<30%）、B组（n=25，LVEF 40%~50%）、C组（n=25，LVEF≥50%）三组，另根据随访1年后是否存活分为生存组（n=51）和死亡组（n=29）。比较不同组别临床相关指标，采用Pearson检验分析患者临床特征与慢性心力衰竭患者心功能、预后之间的相关性，采用多因素Logistic回归分析影响慢性心力衰竭患者心功能、预后的独立危险因素。结果：A组的心率及患有冠心病、心律失常1年以上、合并非心血管疾病人数占比、LAD、RAD、Scr、Hcy水平高于B组和C组（P<0.05）。死亡组的心率及患有冠心病、心律失常1年以上、LAD、RAD、Scr水平明显高于生存组（P<0.05）。Pearson相关性检验显示，心率、冠心病、心律失常、合并非心血管疾病、LAD、RAD、Scr、Hcy水平与慢性心力衰竭患者心功能之间呈正相关（P<0.05）；心率、冠心病、心律失常、LAD、RAD、Scr水平与慢性心力衰竭患者预后之间呈正相关（P<0.05）。多因素Logistic回归分析结果显示，心率、冠心病、心律失常、合并非心血管疾病、LAD、RAD、Scr、Hcy水平是影响慢性心力衰竭患者心功能的独立危险因素（P<0.05）；心率、冠心病、心律失常、LAD、RAD、Scr水平是影响慢性心力衰竭患者预后的独立危险因素（P<0.05）。结论：心率、冠心病、心律失常、LAD、RAD、Scr水平与慢性心力衰竭患者心功能、预后之间均呈正相关，是影响慢性心力衰竭患者心功能、预后的独立危险因素，可用来预测慢性心力衰竭的发生。     

Soft Tissue Modelling of Cardiac Fibres for Use in Coupled Mechano-Electric Simulations

The numerical solution of the coupled system of partial differential and ordinary differential equations that model the whole heart in three dimensions is a considerable computational challenge. As a consequence, it is not computationally practical—either in terms of memory or time—to repeat simulations on a finer computational mesh to ensure that convergence of the solution has been attained. In an attempt to avoid this problem while retaining mathematical rigour, we derive a one dimensional model of a cardiac fibre that takes account of elasticity properties in three structurally defined axes within the myocardial tissue. This model of a cardiac fibre is then coupled with an electrophysiological cell model and a model of cellular electromechanics to allow us to simulate the coupling of the electrical and mechanical activity of the heart. We demonstrate that currently used numerical methods for coupling electrical and mechanical activity do not work in this case, and identify appropriate numerical techniques that may be used when solving the governing equations. This allows us to perform a series of simulations that: (i) investigate the effect of some of the assumptions inherent in other models; and (ii) reproduce qualitatively some experimental observations.     

Chronic cardiac resynchronization therapy and reverse ventricular remodeling in a model of nonischemic cardiomyopathy

While cardiac resynchronization therapy (CRT) has been shown to reduce morbidity and mortality in heart failure (HF) patients, the fundamental mechanisms for the efficacy of CRT are poorly understood. The lack of understanding of these basic mechanisms represents a significant barrier to our understanding of the pathogenesis of HF and potential recovery mechanisms. Our purpose was to determine cellular mechanisms for the observed improvement in chronic HF after CRT. We used a canine model of chronic nonischemic cardiomyopathy. After 15 months, dogs were randomized to continued RV tachypacing (untreated HF) or CRT for an additional 9 months. Six minute walk tests, echocardiograms, and electrocardiograms were done to assess the functional response to therapy. Left ventricular (LV) midmyocardial myocytes were isolated to study electrophysiology and intracellular calcium regulation. Compared to untreated HF, CRT improved HF-induced increases in LV volumes, diameters and mass (p<0.05). CRT reversed HF-induced prolongations in LV myocyte repolarization (p<0.05) and normalized HF-induced depolarization (p<0.03) of the resting membrane potential. CRT improved HF-induced reductions in calcium (p<0.05). CRT did not attenuate the HF-induced increases in LV interstitial fibrosis. Using a translational approach in a chronic HF model, CRT significantly improved LV structure; this was accompanied by improved LV myocyte electrophysiology and calcium regulation. The beneficial effects of CRT may be attributable, in part, to improved LV myocyte function.     

Dual effects of cyclic ADP-ribose on sarcoplasmic reticulum Ca2+ release and storage in cardiac myocytes isolated from guinea-pig and rat ventricle

The actions of cyclic ADP-ribose (cADPR), a regulator of Ca2+-induced Ca2+ release (CICR), were investigated on Ca2+ release and sarcoplasmic reticulum (SR) Ca2+ loading in cardiac myocytes at physiological temperature. In guinea-pig ventricular cells, cADPR, applied via patch pipette or from photorelease of its caged derivative, increased contraction amplitude and whole-cell Ca2+ transients, without affecting SR Ca2+ load (measured in response to rapid caffeine application). Under voltage-clamp conditions, photorelease of caged cADPR enhanced Ca2+ transient magnitude without affecting the peak amplitude of L-type Ca2+ current or its rate of decay, indicative of an increase in CICR gain. In rat permeabilised ventricular myocytes, rapid application of cADPR increased Ca2+ spark frequency within 30 s, and this effect was maintained over a 10 min exposure. Enhancement of spark frequency was not associated with changes in SR Ca2+ load at 30 s and 3 min of exposure to cADPR; however, prolonged exposure (10 min) was associated with an increased SR Ca2+ load (32+/-7%). The observations are consistent with dual actions of cADPR: a rapid effect on CICR that does not depend on an increased SR Ca2+ load, and an additional slower effect that is associated with enhanced SR Ca2+ levels.     

Reactive oxygen species trigger ischemic and pharmacological postconditioning: in vivo and in vitro characterization

Reactive oxygen species (ROS) generated by ischemic and pharmacological preconditioning are known to act as triggers of cardiac protection; however, the involvement of ROS in ischemic and pharmacological postconditioning (PostC) in vivo and in vitro is unknown. We tested the hypothesis that ROS are involved in PostC in the mouse heart in vivo and in the isolated adult cardiac myocyte (ACM). Mice were subjected to 30 min coronary artery occlusion followed by 2 h of reperfusion with or without ischemic or pharmacologic PostC (three cycles of 20 s reperfusion/ischemia; 1.4% isoflurane; 10 mg/kg SNC-121). Additional groups were treated with 2-mercaptopropionyl glycine (MPG), a ROS scavenger, 10 min before or after the PostC stimuli. Ischemia-, isoflurane-, and SNC-121- induced PostC reduced infarct size (24.1+/-3.2, 15.7+/-2.6, 24.9+/-2.6%, p<0.05, respectively) compared to the control group (43.4+/-3.3%). These cardiac protective effects were abolished by MPG when administered before (40.0+/-3.6, 39.3+/-3.1, 38.5+/-1.6%, respectively), but not after the PostC stimuli (26.6+/-2.3, 17.0+/-2.2, 23.9+/-1.7%, respectively). Additionally, ACM were subjected to a simulated ischemia/reperfusion protocol with isoflurane and SNC PostC. Isoflurane- and SNC-induced PostC in vitro were abolished by prior treatment with MPG. These data indicate that ROS signaling is an essential trigger of ischemic and pharmacological PostC and this is occurring at the level of the cardiac myocyte.     

Down-regulation of mitofusin-2 expression in cardiac hypertrophy in vitro and in vivo

Mitofusin-2 (Mfn2) suppresses smooth muscle cell proliferation through inhibition of the Ras-extracellular signal-regulated kinases (ERK1/2) pathway. Since the ERK1/2 pathway is implicated in mediating hypertrophic signaling, we studied the changes in Mfn2 in cardiac hypertrophy using in vitro and in vivo models. Phenylephrine was used to induce hypertrophy in neonatal rat ventricular myocytes (NRVMs). In vivo hypertrophy models included spontaneously hypertensive rats (SHR), pressure-overload hypertrophy by transverse aortic constriction (TAC), hypertrophy of non-infarcted myocardium following myocardial infarction (MI), and cardiomyopathy due to cardiac-restricted overexpression of beta(2)-adrenergic receptors (beta(2)-TG). We determined hypertrophic parameters and analysed expression of atrial natriuretic peptide (ANP) and Mfn2 by real-time PCR. Phosphorylated-ERK1/2 (phospho-ERK) was measured by Western blot. Mfn2 was downregulated in phenylephrine treated NRCMs (by approximately 40%), hypertrophied hearts from SHR (by approximately 80%), mice with TAC (at 1 and 3 weeks, by approximately 50%), and beta(2)-TG mice (by approximately 20%). However, Mfn2 was not downregulated in hypertrophied hearts with 15 weeks of TAC, nor in hypertrophied non-infarcted myocardium following MI. phospho-ERK1/2 was increased in hypertrophied myocardium at 1 week post-TAC, but not in non-infarcted myocardium after MI, indicating that downregulated Mfn2 may be accompanied by an increase of phospho-ERK1/2. This study shows, for the first time, downregulated Mfn2 expression in hypertrophied hearts, which depends on the etiology and time course of hypertrophy. Further study is required to examine the causal relationship between Mfn2 and cardiac hypertrophy.