Project description:Cardiac hypertrophy can be broadly classified as either physiological or pathological. Physiological stimulus such as exercise cause adaptive cardiac hypertrophy and normal heart function. Pathological stimulus such as hypertension and aortic valvular stenosis cause maladaptive cardiac remodeling and ultimately heart failure. Syndecan 4(synd4) is a transmembrane proteoglycan and identified to be involved in cardiac adaptation after injury. Whether it takes part in physiological cardiac hypertrophy is unclear. We observed up-regulation of synd4 in exercise-induced hypertrophic myocardium. To evaluate the role of synd4 in the physiological form of cardiac hypertrophy, mice lacking synd4 (synd4-/-) were exercised by swimming for 4 weeks. Ultrasonic cardiogram (UCG) and histological analysis revealed that swimming-induced the hypertrophic phenotype was blunted in syn4-/- compared with WT mice. The swimming-induced activation of Akt, a key molecule in physiological hypertrophy was also decreased than that seen in wild-type controls. In cultured cardiomyocytes, synd4 over expression could induce cell enlargement, protein synthesis, and distinct physiological molecular alternation. Akt activation was also observed in synd4 over expressed cardiomyocytes. Furthermore inhibition of Protein kinase C (PKC) prevented the synd4 induced hypertrophic phenotype and Akt phosphorylation. This study identified an essential role of synd4 in mediation of physiological cardiac hypertrophy.

Project description:The insulin/IGF-IRS-PI3K-Akt pathway is highly conserved in evolution. To test whether this signaling cascade determines organ size in vertebrates, we have recently created mouse lines transgenic for constitutively active (caPI3K) and dominant-negative forms of PI3K (dnPI3K) (Shioi et al., 2000). Transgene expression is driven by the cardiac-specific a -myosin heavy chain (MHC) promoter. Both transgenic lines are characterized by moderate but highly consistent changes in heart size, despite the fact that body weight and the size of other organs are completely normal. caPI3K transgenic animals have hearts 20% larger than those of wild type littermates, whereas dnPI3K mice have hearts that are 17% smaller. The observed changes in heart size correlate with an appropriate increase or decrease in the size of transgenic cardiomyocytes. These hearts do not have cardiomyopathic changes, since the contractile function of transgenic hearts is normal, and signs of necrosis, apoptosis, or interstitial fibrosis are absent (see Physiology). These data suggest an autonomous role for PI3K in cell size regulation. Our goal is now to determine how activation of this system translates into changes in cell size by identifying the trigger and components of this signaling cascade. Heterozygous caPI3K (constitutively active PI3K) and dnPI3K (dominant-negative PI3K) transgenic female mice (5-14 months) compared with non-transgenic littermates. Transgene expression driven by the a -myosin heavy chain (a -MHC) promoter. Keywords: other

Project description:Cardiac hypertrophy was induced by treadmill running. Sedentary animals served as controls. Gene expression was determined by Affymetrix RGU34A GeneChip's to identify genes with differential expression in an adaptive model of cardiac hypertrophy. Keywords: other

Project description:The receptors for IGF-I (IGF-IR) and insulin (IR) have been implicated in physiological cardiac growth, but it is unknown whether IGF-IR or IR signaling are critically required. We generated mice with cardiomyocyte-specific knockout of IGF-IR (CIGF1RKO) and compared them with cardiomyocyte-specific insulin receptor knockout (CIRKO) mice in response to 5 wk exercise swim training. Cardiac development was normal in CIGF1RKO mice, but the hypertrophic response to exercise was prevented. In contrast, despite reduced baseline heart size, the hypertrophic response of CIRKO hearts to exercise was preserved. Exercise increased IGF-IR content in control and CIRKO hearts. Akt phosphorylation increased in exercise-trained control and CIRKO hearts and, surprisingly, in CIGF1RKO hearts as well. In exercise-trained control and CIRKO mice, expression of peroxisome proliferator-activated receptor-gamma coactivator-1alpha (PGC-1alpha) and glycogen content were both increased but were unchanged in trained CIGF1RKO mice. Activation of AMP-activated protein kinase (AMPK) and its downstream target eukaryotic elongation factor-2 was increased in exercise-trained CIGF1RKO but not in CIRKO or control hearts. In cultured neonatal rat cardiomyocytes, activation of AMPK with 5-aminoimidazole-4-carboxamide-1-beta-D-ribofuranoside (AICAR) prevented IGF-I/insulin-induced cardiomyocyte hypertrophy. These studies identify an essential role for IGF-IR in mediating physiological cardiomyocyte hypertrophy. IGF-IR deficiency promotes energetic stress in response to exercise, thereby activating AMPK, which leads to phosphorylation of eukaryotic elongation factor-2. These signaling events antagonize Akt signaling, which although necessary for mediating physiological cardiac hypertrophy, is insufficient to promote cardiac hypertrophy in the absence of myocardial IGF-I signaling.

Project description:Physiological cardiac hypertrophy is associated with mitochondrial adaptations that are characterized by activation of PGC-1alpha and increased fatty acid oxidative (FAO) capacity. It is widely accepted that phosphatidylinositol 3-kinase (PI3K) signaling to Akt1 is required for physiological cardiac growth. However, the signaling pathways that coordinate physiological hypertrophy and metabolic remodeling are incompletely understood. We show here that activation of PI3K is sufficient to increase myocardial FAO capacity and that inhibition of PI3K signaling prevents mitochondrial adaptations in response to physiological hypertrophic stimuli despite increased expression of PGC-1alpha. We also show that activation of the downstream kinase Akt is not required for the mitochondrial adaptations that are secondary to PI3K activation. Thus, in physiological cardiac growth, PI3K is an integrator of cellular growth and metabolic remodeling. Although PI3K signaling to Akt1 is required for cellular growth, Akt-independent pathways mediate the accompanying mitochondrial adaptations.

Project description:Comparative analysis of mouse cardiac left ventricle gene expression: voluntary wheel exercise and pregnancy-induced cardiac hypertrophy We performed microarray analysis on RNA from left ventricles of mice in non-pregnant diestrus cycle, mid-pregnancy (MP), late-pregnancy (LP), and immediate post-partum (0PP). These were compared to 7days (7EX) and 21 days (21EX) of voluntary wheel running exercise.

Project description:Comparative analysis of mouse cardiac left ventricle gene expression: voluntary wheel exercise and pregnancy-induced cardiac hypertrophy

Project description:Phosphoinositide-dependent kinase l (PDK1) phosphorylates and activates multiple AGC serine kinases, including protein kinase B (PKB), p70Ribosomal S6 kinase (S6K) and p90Ribosomal S6 kinase (RSK). PDK1 is required for thymocyte differentiation and proliferation, and herein, we explore the molecular basis for these essential functions of PDK1 in T lymphocyte development. A key finding is that PDK1 is required for the expression of key nutrient receptors in T cell progenitors: CD71 the transferrin receptor and CD98 a subunit of L-amino acid transporters. PDK1 is also essential for Notch-mediated trophic and proliferative responses in thymocytes. A PDK1 mutant PDK1 L155E, which supports activation of PKB but no other AGC kinases, can restore CD71 and CD98 expression in pre-T cells and restore thymocyte differentiation. However, PDK1 L155E is insufficient for thymocyte proliferation. The role of PDK1 in thymus development thus extends beyond its ability to regulate PKB. In addition, PDK1 phosphorylation of AGC kinases such as S6K and RSK is also necessary for thymocyte development.

Project description:BackgroundIsoproterenol-induced cardiac hypertrophy in mice has been used in a number of studies to model human cardiac disease. In this study, we compared the transcriptional response of the heart in this model to other animal models of heart failure, as well as to the transcriptional response of human hearts suffering heart failure.ResultsWe performed microarray analyses on RNA from mice with isoproterenol-induced cardiac hypertrophy and mice with exercise-induced physiological hypertrophy and identified 865 and 2,534 genes that were significantly altered in pathological and physiological cardiac hypertrophy models, respectively. We compared our results to 18 different microarray data sets (318 individual arrays) representing various other animal models and four human cardiac diseases and identified a canonical set of 64 genes that are generally altered in failing hearts. We also produced a pairwise similarity matrix to illustrate relatedness of animal models with human heart disease and identified ischemia as the human condition that most resembles isoproterenol treatment.ConclusionThe overall patterns of gene expression are consistent with observed structural and molecular differences between normal and maladaptive cardiac hypertrophy and support a role for the immune system (or immune cell infiltration) in the pathology of stress-induced hypertrophy. Cross-study comparisons such as the results presented here provide targets for further research of cardiac disease that might generally apply to maladaptive cardiac stresses and are also a means of identifying which animal models best recapitulate human disease at the transcriptional level.

Project description:Alterations in intracellular Ca(2+) homeostasis are an important trigger of pathological cardiac remodeling; however, mechanisms governing context-dependent changes in Ca(2+) influx are poorly understood. Store-operated Ca(2+) entry (SOCE) is a major mechanism regulating Ca(2+) trafficking in numerous cell types, yet its prevalence in adult heart and possible role in physiology and disease are each unknown. The Ca(2+)-binding protein, stromal interaction molecule 1 (STIM1), is a Ca(2+) sensor in the sarcoplasmic reticulum (SR), capable of triggering SOCE by interacting with plasma membrane Ca(2+) channels. We report that SOCE is abundant and robust in neonatal cardiomyocytes; however, SOCE is absent from adult cardiomyocytes. Levels of STIM1 transcript and protein correlate with the amplitude of SOCE, and manipulation of STIM1 protein levels (via shRNA) or activity (via expression of constitutively active or dominant-negative mutants) reveals a critical role for STIM1 in activating SOCE in cardiac myocytes. In neonatal hearts a recently identified STIM1 splice variant (STIM1L) is predominant but diminishes with maturation, only to reemerge with agonist- or afterload-induced cardiac stress. To test for pathophysiological relevance, we evaluated both in vitro and in vivo models of cardiac hypertrophy, finding that STIM1 expression is re-activated by pathological stress to trigger significant SOCE-dependent Ca(2+) influx. STIM1 amplifies agonist-induced hypertrophy via activation of the calcineurin-NFAT pathway. Importantly, inhibition of STIM1 suppresses agonist-triggered hypertrophy, pointing to a requirement for SOCE in this remodeling response. Stress-triggered STIM1 re-expression, and consequent SOCE activation, are critical elements in the upstream, Ca(2+)-dependent control of pathological cardiac hypertrophy.