deltaPKC participates in the endoplasmic reticulum stress-induced response in cultured cardiac myocytes and ischemic heart

The cellular response to excessive endoplasmic reticulum (ER) stress includes the activation of signaling pathways, which lead to apoptotic cell death. Here we show that treatment of cultured cardiac myocytes with tunicamycin, an agent that induces ER stress, causes the rapid translocation of deltaPKC to the ER. We further demonstrate that inhibition of deltaPKC using the deltaPKC-specific antagonist peptide, deltaV1-1, reduces tunicamycin-induced apoptotic cell death, and inhibits expression of specific ER stress response markers such as CHOP, GRP78 and phosphorylation of JNK. The physiological importance of deltaPKC in this event is further supported by our findings that the ER stress response is also induced in hearts subjected to ischemia and reperfusion injury and that this response also involves deltaPKC translocation to the ER. We found that the levels of the ER chaperone, GRP78, the spliced XBP-1 and the phosphorylation of JNK are all increased following ischemia and reperfusion and that deltaPKC inhibition by deltaV1-1 blocks these events. Therefore, ischemia-reperfusion injury induces ER stress in the myocardium in a mechanism that requires deltaPKC activity. Taken together, our data show for the first time that deltaPKC activation plays a critical role in the ER stress-mediated response and the resultant cell death.     

DeltaPKC-mediated activation of epsilonPKC in ethanol-induced cardiac protection from ischemia

Previous studies have demonstrated that acute ethanol exposure induces activation of delta protein kinase C (deltaPKC) and epsilonPKC, and mimics ischemic preconditioning via epsilonPKC activation. However, the role of deltaPKC isozyme in ischemia and reperfusion is still controversial. Here, we investigated the role of deltaPKC in ethanol-induced cardioprotection using a selective deltaPKC activator (psideltaRACK), or inhibitor (deltaV1-1), and a selective epsilonPKC inhibitor (epsilonV1-2) in isolated mouse hearts. Mice were injected intraperitoneally or by gavage with ethanol, regulators of delta and epsilonPKC or an adenosine A1 receptor blocker (DPCPX). Isolated perfused mouse hearts were subjected to a 30-min global ischemia and a 120-min reperfusion, ex vivo. Injection of 0.5 g/kg ethanol 1 h, but not 10 min, before ischemia reduced infarct size and CPK release. Pretreatment with epsilonV1-2 abolished this ethanol-induced cardioprotection. Pretreatment with deltaV1-1 induced cardioprotection when injected with ethanol (0.5 g/kg) 10 min before ischemia, but deltaV1-1 partly inhibited ethanol-induced cardioprotection when injected with ethanol 1-h before the onset of ischemia. psideltaRACK injection 1 h, but not 10 min, before ischemia induced cardioprotection and translocation of epsilonPKC from the cytosol to the particulate fraction. Pretreatment with DPCPX or epsilonV1-2 inhibited psideltaRACK-induced cardioprotection and translocation of epsilonPKC. Therefore, activation of deltaPKC-induced by ethanol or by the deltaPKC activator is cardioprotective, provided that sufficient time passes to allow deltaPKC-induced activation of epsilonPKC, an A1 adenosine receptor-dependent process.     

Impaired perfusion after myocardial infarction is due to reperfusion-induced deltaPKC-mediated myocardial damage

OBJECTIVE: To improve myocardial flow during reperfusion after acute myocardial infarction and to elucidate the molecular and cellular basis that impedes it. According to the AHA/ACC recommendation, an ideal reperfusion treatment in patients with acute myocardial infarction (AMI) should not only focus on restoring flow in the occluded artery, but should aim to reduce microvascular damage to improve blood flow in the infarcted myocardium. METHODS: Transgenic mouse hearts expressing the deltaPKC (protein kinase C) inhibitor, deltaV1-1, in their myocytes only were treated with or without the deltaPKC inhibitor after ischemia in an ex vivo AMI model. deltaV1-1 or vehicle was also delivered at reperfusion in an in vivo porcine model of AMI. Microvascular dysfunction was assessed by physiological and histological measurements. RESULTS: deltaPKC inhibition in the endothelial cells improved myocardial perfusion in the transgenic mice. In the porcine in vivo AMI model, coronary flow reserve (CFR), which is impaired for 6 days following infarction, was improved immediately following a one-minute treatment at the end of the ischemic period with the deltaPKC-selective inhibitor, deltaV1-1 ( approximately 250 ng/kg), and was completely corrected by 24 h. Myocardial contrast echocardiography, electron microscopy studies, and TUNEL staining demonstrated deltaPKC-mediated microvascular damage. epsilonPKC-induced preconditioning, which also reduces infarct size by >60%, did not improve microvascular function. CONCLUSIONS: These data suggest that deltaPKC activation in the microvasculature impairs blood flow in the infarcted tissue after restoring flow in the occluded artery and that AMI patients with no-reflow may therefore benefit from treatment with a deltaPKC inhibitor given in conjunction with removal of the coronary occlusion.     

Cardiomyocyte-specific desmin rescue of desmin null cardiomyopathy excludes vascular involvement

Mice deficient in desmin, the muscle-specific member of the intermediate filament gene family, display defects in all muscle types and particularly in the myocardium. Desmin null hearts develop cardiomyocyte hypertrophy and dilated cardiomyopathy (DCM) characterized by extensive myocyte cell death, calcific fibrosis and multiple ultrastructural defects. Several lines of evidence suggest impaired vascular function in desmin null animals. To determine whether altered capillary function or an intrinsic cardiomyocyte defect is responsible for desmin null DCM, transgenic mice were generated to rescue desmin expression specifically to cardiomyocytes. Desmin rescue mice display a wild-type cardiac phenotype with no fibrosis or calcification in the myocardium and normalization of coronary flow. Cardiomyocyte ultrastructure is also restored to normal. Markers of hypertrophy upregulated in desmin null hearts return to wild-type levels in desmin rescue mice. Working hearts were perfused to assess coronary flow and cardiac power. Restoration of a wild-type cardiac phenotype in a desmin null background by expression of desmin specifically within cardiomyocyte indicates that defects in the desmin null heart are due to an intrinsic cardiomyocytes defect rather than compromised coronary circulation.     

Expression of contractile and cytoskeletal proteins in myocardium of patients with dilated cardiomyopathy.

Dilated cardiomyopathy (DCM) is characterized by enlargement and dilation of all heart compartments associated with serious decrease of its contractile function. DCM hallmark is the combination of dystrophic and hypertrophic alterations of cardiomyocytes. Since the power output of cardiac cells is directly related to remodeling of their contractile machinery we investigated expression of selected contractile and cytoskeletal proteins in the left ventricle of DCM patients using immunoblotting. The content of the recognized protein markers of cardiomyocyte hypertrophy such as tubulin, desmin and slow skeletal myosin heavy chain isoform, MHCbeta, was significantly elevated in DCM compared to normal myocardium. In addition, marked increase in the content of several smooth muscle proteins (smooth muscle alpha-actin, Myosin Light Chain Kinase, Kinase Related protein SM22) that are normally expressed in embryonic myocardium, was observed in DCM hearts. Thus, cardiomyocyte hypertrophy in DCM is associated with activation of embryonic protein expression program and smooth muscle proteins could serve as markers of this process. Understanding their involvement in sarcomere assembly and pathways of their expression activation during cardiac hypertrophy may bring new insights in treatment of various forms of cardiomyopathy.     

ROCK1 plays an essential role in the transition from cardiac hypertrophy to failure in mice

Pathological cardiac hypertrophy caused by diverse etiologies eventually leads to cardiac dilation and functional decompensation. We have recently reported that genetic deletion of Rho-associated coiled-coil containing protein kinase 1 (ROCK1) inhibited several pathological events including cardiomyocyte apoptosis in compensated hypertrophic hearts. The present study investigated whether ROCK1 deficiency can prevent the transition from hypertrophy to heart failure. Transgenic mice with cardiac-restricted overexpression of Gαq develop compensated cardiac hypertrophy at young ages, but progress into lethal cardiomyopathy accompanied by increased apoptosis after pregnancy or at old ages. The studies were first carried out using age- and pregnancy-matched wild-type, Gαq, ROCK1^−/−, and Gαq/ROCK1^−/− mice. The potent beneficial effect of ROCK1 deletion is demonstrated by abolishment of peripartum mortality, and significant attenuation of left ventricular (LV) dilation, wall thinning, and contractile dysfunction in the peripartum Gαq transgenic mice. Increase in cardiomyocyte apoptosis was suppressed by ROCK1 deletion, associated with increased extracellular signal-regulated kinase/mitogen-activated protein kinase (ERK/MAPK) activation and inhibition of mitochondrial translocation of Bax. In addition, ROCK1 deficiency also improved survival, inhibited cardiomyocyte apoptosis, and preserved LV dimension and function in old Gαq mice at 12 months. Furthermore, transgenic overexpression of ROCK1 increased cardiomyocyte apoptosis and accelerated hypertrophic decompensation in Gαq hearts in the absence of pregnancy stress. The present study provides for the first time in vivo evidence for the long-term beneficial effects of ROCK1 deficiency in hypertrophic decompensation and suggests that ROCK1 may be an attractive therapeutic target to limit heart failure progression.     

Preserved cardiomyocyte function and altered desmin pattern in transgenic mouse model of dilated cardiomyopathy

Taking advantage of the unique model of slowly developing dilated cardiomyopathy in mice with cardiomyocyte-specific transgenic overexpression of activated Gαq protein (Tgαq*44 mice) we analyzed the contribution of the cardiomyocyte malfunction, fibrosis and cytoskeleton remodeling to the development of heart failure in this model. Left ventricular (LV) in vivo function, myocardial fibrosis, cytoskeletal proteins expression and distribution, Ca(2+) handling and contractile function of isolated cardiomyocytes were evaluated at the stages of the early, compensated, and late, decompensated heart failure in 4-, 12- and 14-month-old Tgαq*44 mice, respectively, and compared to age-matched wild-type FVB mice. In the 4-month-old Tgαq*44 mice significant myocardial fibrosis, moderate myocyte hypertrophy and increased expression of regularly arranged and homogenously distributed desmin accompanied by increased phosphorylation of desmin chaperone protein, αB-crystallin, were found. Cardiomyocyte shortening, Ca(2+) handling and LV function were not altered. At 12 and 14 months of age, Tgαq*44 mice displayed progressive deterioration of the LV function. The contractile performance of isolated myocytes was still preserved, and the amplitude of Ca(2+) transients was even increased probably due to impairment of Na(+)/Ca(2+) exchanger function, while fibrosis was more extensive than in younger mice. Moreover, substantial disarrangement of desmin distribution accompanied by decreasing phosphorylation of αB-crystallin appeared. In Tgαq*44 mice disarrangement of desmin, at least partly related to inadequate phosphorylation of αB-crystallin seems to be importantly involved in the progressive deterioration of contractile heart function.     

Comparison of two murine models of familial hypertrophic cardiomyopathy

Although sarcomere protein gene mutations cause familial hypertrophic cardiomyopathy (FHC), individuals bearing a mutant cardiac myosin binding protein C (MyBP-C) gene usually have a better prognosis than individuals bearing beta-cardiac myosin heavy chain (MHC) gene mutations. Heterozygous mice bearing a cardiac MHC missense mutation (alphaMHC(403/+) or a cardiac MyBP-C mutation (MyBP-C(t/+)) were constructed as murine FHC models using homologous recombination in embryonic stem cells. We have compared cardiac structure and function of these mouse strains by several methods to further define mechanisms that determine the severity of FHC. Both strains demonstrated progressive left ventricular (LV) hypertrophy; however, by age 30 weeks, alphaMHC(403/+) mice demonstrated considerably more LV hypertrophy than MyBP-C(t/+) mice. In older heterozygous mice, hypertrophy continued to be more severe in the alphaMHC(403/+) mice than in the MyBP-C(t/+) mice. Consistent with this finding, hearts from 50-week-old alphaMHC(403/+) mice demonstrated increased expression of molecular markers of cardiac hypertrophy, but MyBP-C(t/+) hearts did not demonstrate expression of these molecular markers until the mice were >125 weeks old. Electrophysiological evaluation indicated that MyBP-C(t/+) mice are not as likely to have inducible ventricular tachycardia as alphaMHC(403/+) mice. In addition, cardiac function of alphaMHC(403/+) mice is significantly impaired before the development of LV hypertrophy, whereas cardiac function of MyBP-C(t/+) mice is not impaired even after the development of cardiac hypertrophy. Because these murine FHC models mimic their human counterparts, we propose that similar murine models will be useful for predicting the clinical consequences of other FHC-causing mutations. These data suggest that both electrophysiological and cardiac function studies may enable more definitive risk stratification in FHC patients.     

Reperfusion-induced translocation of deltaPKC to cardiac mitochondria prevents pyruvate dehydrogenase reactivation

Cardiac ischemia and reperfusion are associated with loss in the activity of the mitochondrial enzyme pyruvate dehydrogenase (PDH). Pharmacological stimulation of PDH activity improves recovery in contractile function during reperfusion. Signaling mechanisms that control inhibition and reactivation of PDH during reperfusion were therefore investigated. Using an isolated rat heart model, we observed ischemia-induced PDH inhibition with only partial recovery evident on reperfusion. Translocation of the redox-sensitive delta-isoform of protein kinase C (PKC) to the mitochondria occurred during reperfusion. Inhibition of this process resulted in full recovery of PDH activity. Infusion of the deltaPKC activator H2O2 during normoxic perfusion, to mimic one aspect of cardiac reperfusion, resulted in loss in PDH activity that was largely attributable to translocation of deltaPKC to the mitochondria. Evidence indicates that reperfusion-induced translocation of deltaPKC is associated with phosphorylation of the alphaE1 subunit of PDH. A potential mechanism is provided by in vitro data demonstrating that deltaPKC specifically interacts with and phosphorylates pyruvate dehydrogenase kinase (PDK)2. Importantly, this results in activation of PDK2, an enzyme capable of phosphorylating and inhibiting PDH. Thus, translocation of deltaPKC to the mitochondria during reperfusion likely results in activation of PDK2 and phosphorylation-dependent inhibition of PDH.     

The absence of desmin leads to cardiomyocyte hypertrophy and cardiac dilation with compromised systolic function

Desmin is the muscle-specific member of the intermediate filament family of cytoskeletal proteins, expressed both in striated and smooth muscle tissues. In mature striated muscle fibers, the desmin filament lattice surrounds the Z-discs, interconnects them to each other and links the entire contractile apparatus to the sarcolemmal cytoskeleton, cytoplasmic organelles and the nucleus. There have been increasing reports of human cardiomyopathies associated with abnormal accumulation and aggregation of desmin filaments. Recently identified desmin mutations in humans suffering from skeletal muscle myopathy and cardiomyopathy suggest that these diseases might arise as a consequence of impaired function of desmin filaments. Previous generation of desmin null mice in our laboratory demonstrated that the absence of desmin results in myocyte ultrastructural defects and myocyte cell death leading to fibrosis and calcification of the myocardium. However, the effects that these defects have on cardiac function were not addressed. To further our understanding of desmin function in vivo, and in order to address the direct involvement of desmin in cardiomyopathy, we investigated the effect of the absence of desmin on myocardial mass, myocyte size and shape, changes in gene expression and cardiac systolic and diastolic function in mice. Morphometric characterization of isolated cardiomyocytes demonstrated a 24% increase in cell volume in the desmin null mice, solely due to an increase in transverse section area, suggesting for the first time that mice lacking the intermediate filament protein desmin develop concentric cardiomyocyte hypertrophy. This type of hypertrophy was accompanied by induction of embryonic gene expression and later by ventricular dilatation, and compromised systolic function. These results demonstrate that desmin is essential for normal cardiac function, and they suggest that the absence of an intact desmin filament system, rather than accumulation of the protein, may be responsible for the pathology seen in some of the desmin associated cardiomyopathies.     

Cardiotrophic effects of protein kinase C epsilon: analysis by in vivo modulation of PKCepsilon translocation

Protein kinase C (PKC) is a key mediator of many diverse physiological and pathological responses. Although little is known about the specific in vivo roles of the various cardiac PKC isozymes, activation-induced translocation of PKC is believed to be the primary determinant of isozyme-specific functions. Recently, we have identified a catalytically inactive peptide translocation inhibitor (epsilonV1) and translocation activator (psiepsilonRACK [receptors for activated C kinase]) specifically targeting PKCepsilon. Using cardiomyocyte-specific transgenic expression of these peptides, we combined loss- and gain-of-function approaches to elucidate the in vivo consequences of myocardial PKCepsilon signaling. As expected for a PKCepsilon RACK binding peptide, confocal microscopy showed that epsilonV1 decorated cross-striated elements and intercalated disks of cardiac myocytes. Inhibition of cardiomyocyte PKCepsilon by epsilonV1 at lower expression levels upregulated alpha-skeletal actin gene expression, increased cardiomyocyte cell size, and modestly impaired left ventricular fractional shortening. At high expression levels, epsilonV1 caused a lethal dilated cardiomyopathy. In contrast, enhancement of PKCepsilon translocation with psiepsilonRACK resulted in selectively increased beta myosin heavy chain gene expression and normally functioning concentric ventricular remodeling with decreased cardiomyocyte size. These results identify for the first time a role for PKCepsilon signaling in normal postnatal maturational myocardial development and suggest the potential for PKCepsilon activators to stimulate "physiological" cardiomyocyte growth.     

Molecular characterization of the ventricular conduction system in the developing mouse heart: topographical correlation in normal and congenitally malformed hearts

OBJECTIVES: Within the adult heart, it is convention to distinguish the conduction system and working (atrial and ventricular) myocardium. The adult conduction system (CS) comprises the sinoatrial (SAN), and atrioventricular (AVN) nodes, the atrioventricular bundle (AVB), the bundle branches and the peripheral Purkinje fibers, each of which display distinct functional properties and distinct profile of gene expression. Characterization of the mouse cardiac conduction system during development is rudimentary at present, even though genetically-modified mice are an increasing source of information regarding cardiac function and embryonic heart development. METHODS: We have performed a detailed study of the pattern of expression of myosin heavy chain (MHC), myosin light chain (MLC), troponin I (TnI) isoforms, connexin 43 (Cx43), desmin and alpha-smooth muscle actin (alpha-SMA), in the ventricular conduction system of normal and congenitally malformed mouse hearts (iv background) from embryonic day 14.5 to 19.5. RESULTS: The AVN is characterized by co-expression of MHC and MLC isoforms and no detectable expression of Cx43, desmin or alpha-SMA. The AVB expresses betaMHC and MLC2v, but no alphaMHC, MLC2a, Cx43, desmin or alpha-SMA. The right and left bundle branches display enhanced expression of desmin and alpha-SMA but no Cx43. The normal expression profile is maintained in congenitally malformed hearts such as double-outlet right ventricle and common atrioventricular canal. Three-dimensional reconstruction of the conduction system shows normal arrangement of the bundle branches in congenitally malformed hearts, but abnormal location and/or extension of the AVN. CONCLUSIONS: Molecular characterization allows to follow the development of the CS in both, normal and malformed mouse hearts. Normal phenotypic expression of the CS is independent of heart situs but shows minor modifications in the presence of heart malformations. It is concluded that the AVN derives from the atrioventricular canal myocardium, the bundle of His from the ventricular myocardium, and the bundle branches from the ventricular trabeculations. Our results do not provide evidence to support an extra-cardiac origin of the ventricular CS.     

Enhanced myocyte contractility and Ca2+ handling in a calcineurin transgenic model of heart failure

OBJECTIVE: Impaired myocyte Ca2+ handling is a common characteristic of failing hearts and increases in calcineurin activity, a Ca2+-sensitive phosphatase, have been implicated in heart failure phenotype. Transgenic mice with cardiac-specific expression of an active form of calcineurin display depressed function, hypertrophy and heart failure. We examined whether defects in cardiomyocyte Ca2+ handling properties contribute to the impaired cardiac function in calcineurin transgenic mice. METHODS: The levels of SR Ca2+ handling proteins, SR Ca2+ transport function and cardiomyocyte mechanics, as well as Ca2+ kinetics were examined in mice overexpressing a constitutively active form of calcineurin. RESULTS: Transgenic expression of activated calcineurin catalytic subunit resulted in significant protein increases (66%) in SERCA2 and decreases (35%) in phospholamban, as well as enhanced (approximately 80%) phospholamban phosphorylation. These alterations in the SR Ca2+-transport proteins resulted in increased V(max) and Ca2+-affinity of SERCA2. The myofibrillar Mg-ATPase activity was also significantly increased at pCa>6.0. The enhanced SR Ca2+ handling and Mg-ATPase activity reflected significant elevation in myocyte contractile parameters (3-fold), Ca2+ transient amplitude (1.5-fold) and the rate of Ca2+ signal decay (2-fold). In contrast, in vivo cardiac function assessed by echocardiography, indicated severely depressed contractility in calcineurin hearts. The apparent disparity in contractile properties between the cellular and multicellular preparations may be partially due to tissue remodeling, including interstitial fibrosis and a marked reduction (45%), dephosphorylation (81%) and redistribution of the gap junctional protein connexin-43, which could compromise intercellular communication. CONCLUSION: Despite enhanced SR Ca2+ handling and contractility in myocytes, pathological remodeling and defects in intercellular coupling may underlie contractile dysfunction of the calcineurin hearts.     

Differential protein expression profiling of myocardial tissue in a mouse model of hypertrophic cardiomyopathy

Hypertrophic cardiomyopathy (HCM) is a genetic disorder caused by mutations in genes encoding sarcomere proteins. The mechanisms involved in the development of cardiac hypertrophy and heart failure remain poorly understood. Global proteomic profiling was used to study the cardiac proteome of mice predisposed to developing HCM. Hearts from three groups of mice (n = 3 hearts per group) were studied: non-transgenic (NTG) and cardiac-specific transgenic models over-expressing either the normal (TnI^WT) or a mutant cardiac troponin I gene (Gly203Ser; TnI^G203S). Two-dimensional gel electrophoresis (2-DE) coupled with tandem mass spectrometry was used to identify proteins. Image analysis was performed using Progenesis SameSpots. A total of 34 proteins with at least a twofold change in the TnI^G203S mouse model were identified. Alterations were detected in components involved in energy production, Ca²⁺ handling, and cardiomyocyte structure. Expression level changes in cytoskeletal and contractile proteins were well represented in the study, including the intermediate filament protein desmin, which was further investigated in two additional physiological and pathological settings, i.e., exercise treatment, and severe heart failure in a novel double-mutant TnI-203/MHC-403 model of HCM. This study highlights the potential role of tissue proteomic profiling for mapping proteins, which may be critical in cardiac dysfunction and progression to heart failure in HCM.     

The role of the cytoskeleton in heart failure

The cytoskeleton of cardiac myocytes consists of actin, the intermediate filament desmin and of alpha- and beta-tubulin that form the microtubules by polymerization. Vinculin, talin, dystrophin and spectrin represent a separate group of membrane-associated proteins. In numerous experimental studies, the role of cytoskeletal alterations especially of microtubules and desmin, in cardiac hypertrophy and failure (CHF) has been described. Microtubules were found to be accumulated thereby posing an increased load on myocytes which impedes sarcomere motion and promotes cardiac dysfunction. Other groups were unable to confirm microtubular densification. The possibility exists that these changes are species, load and chamber dependent. Recently, damage of the dystrophin molecule and MLP (muscle LIM protein) were identified as possible causes of CHF. Our own studies in human hearts with chronic CHF due to dilated cardiomyopathy (DCM) showed that a morphological basis of reduced contractile function exists: the cytoskeletal and membrane-associated proteins are disorganized and increased in amount confirming experimental reports. In contrast, the contractile myofilaments and the proteins of the sarcomeric skeleton including titin, alpha-actinin, and myomesin are significantly decreased. These changes can be assumed to occur in stages and are here presented as a testable hypothesis: (1) The early and reversible stage as present in animal experiments is characterized by accumulation of cytoskeletal proteins to counteract an increased strain without loss of contractile material. (2) Further accumulation of microtubules and desmin to compensate for the increasing loss of myofilaments and titin represents the late clinical and irreversible state. We suggest, based on a structural basis for heart failure, an integrative view which closes the gap between changes within cardiac myocytes and the involvement of the extracellular matrix, including the development of fibrosis. These factors contribute significantly to structural ventricular remodeling and dilatation finally resulting in reduced cardiac function.     

AlphaB-crystallin modulates protein aggregation of abnormal desmin

AlphaB-crystallin (CryAB) is the most abundant small heat shock protein in the heart. Upregulation of CryAB in desmin-related myopathy and its downregulation in end-stage congestive heart failure have both been reported. We previously demonstrated via cardiac-specific transgenesis that modest increases in normal CryAB are not detrimental to the heart, whereas expression of the R120G mutation of CryAB caused a desminopathy. It is generally believed that CryAB plays an important role in protecting the intermediate filaments, but the underlying mechanism is unclear. We hypothesized that CryAB protects the desmin filaments via preventing abnormal desmin protein from aggregating adversely. To test this hypothesis in vivo, mice expressing a desmin mutation that causes a desmin-related cardiomyopathy (D7) were bred into the R120G-CryAB transgenic (TG) background to examine the accumulation and aberrant aggregation of desmin protein. Despite lower mRNA expression of D7-des than in the D7-des TG hearts, the double-TG myocardium exhibited significantly higher desmin protein levels and dramatically more aberrant desmin aggregates than the D7-des TG hearts. The double-TG mice displayed a significantly stronger cardiac hypertrophic response, with the mice dying of congestive heart failure before 7 weeks. To explore the ability of wild-type (WT) CryAB to protect against mutant desmin, a desmin mutant was expressed in both the conventional and WT-CryAB stably transfected HEK cells. Significantly less aberrant desmin aggregation was observed in the WT-CryAB-overexpressing cells than in the HEK cells. The results suggest that CryAB modulates abnormal desmin aggregation and can serve a cardioprotective role.     

Cardiac overexpression of melusin protects from dilated cardiomyopathy due to long-standing pressure overload

We have previously shown that genetic ablation of melusin, a muscle specific beta 1 integrin interacting protein, accelerates left ventricle (LV) dilation and heart failure in response to pressure overload. Here we show that melusin expression was increased during compensated cardiac hypertrophy in mice subjected to 1 week pressure overload, but returned to basal levels in LV that have undergone dilation after 12 weeks of pressure overload. To better understand the role of melusin in cardiac remodeling, we overexpressed melusin in heart of transgenic mice. Echocardiography analysis indicated that melusin over-expression induced a mild cardiac hypertrophy in basal conditions (30% increase in interventricular septum thickness) with no obvious structural and functional alterations. After prolonged pressure overload (12 weeks), melusin overexpressing hearts underwent further hypertrophy retaining concentric LV remodeling and full contractile function, whereas wild-type LV showed pronounced chamber dilation with an impaired contractility. Analysis of signaling pathways indicated that melusin overexpression induced increased basal phosphorylation of GSK3beta and ERK1/2. Moreover, AKT, GSK3beta and ERK1/2 were hyper-phosphorylated on pressure overload in melusin overexpressing compared with wild-type mice. In addition, after 12 weeks of pressure overload LV of melusin overexpressing mice showed a very low level of cardiomyocyte apoptosis and stromal tissue deposition, as well as increased capillary density compared with wild-type. These results demonstrate that melusin overexpression allows prolonged concentric compensatory hypertrophy and protects against the transition toward cardiac dilation and failure in response to long-standing pressure overload.     

Alterations in contractile protein composition and function in human atrial dilatation and atrial fibrillation

The cellular mechanisms responsible for contractile dysfunction associated with atrial fibrillation (AF) are still poorly understood. Atrial fibrillation is often preceded by atrial dilatation. This study aimed to explain contractile alterations associated with AF and their relation to atrial dilatation, by studying the relationships between atrial dimensions, contractile protein composition, force production and Ca(2+)-sensitivity. Force development was determined in mechanically isolated single skinned cardiomyocytes from right atrial appendages from patients with sinus rhythm without (SR;n=9), or with atrial dilation (SR+AD;n=11) or atrial fibrillation (AF;n=16). Echocardiography showed that, compared to the SR group, mean right atrial dimensions were increased by 18% and 35% in the SR+AD and AF group, respectively (P<0.05). Protein composition was determined by 1- and 2-dimensional gel electrophoresis. Compared to the SR group, the AF group exhibited: a reduction in the kinetics of force redevelopment (K(tr)) in isolated atrial cardiomyocytes, enhanced protein expression of the slow myosin heavy chain isoform (beta-MHC), an increase in troponin T (TnT) phosphorylation and a marked increase (70%) of the cytoskeletal protein desmin. Significant correlations were observed between the right atrial major axis (RA(major)) and beta-MHC expression as well as the desmin/actin ratio. Our findings indicate that dilatation may influence cardiomyocyte stability through altered desmin expression, but that it does not predispose to the alterations in contractile function observed in AF.