Project description:Insulin-like growth factor-1 (IGF-1) signaling has recently been implicated in the development of cardiac hypertrophy after long-term endurance training, via mechanisms that may involve energetic stress. Given the potential overlap of insulin and IGF-1 signaling we sought to determine if both signaling pathways could contribute to exercise-induced cardiac hypertrophy following shorter-term exercise training. Studies were performed in mice with cardiac-specific IGF-1 receptor (IGF1R) knockout (CIGFRKO), mice with cardiac-specific insulin receptor (IR) knockout (CIRKO), CIGFRKO mice that lacked one IR allele in cardiomyocytes (IGFR-/-IR+/-), and CIRKO mice that lacked one IGF1R allele in cardiomyocytes (IGFR+/-IR-/-). Intravenous administration of IGF-1 or 75 hours of swimming over 4 weeks increased IGF1R tyrosine phosphorylation in the heart in control and CIRKO mice but not in CIGFRKO mice. Intriguingly, IR tyrosine phosphorylation in the heart was also increased following IGF-1 administration or exercise training in control and CIGFRKO mice but not in CIRKO mice. The extent of cardiac hypertrophy following exercise training in CIGFRKO and CIRKO mice was comparable to that in control mice. In contrast, exercise-induced cardiac hypertrophy was significantly attenuated in IGFR-/-IR+/- and IGFR+/-IR-/- mice. Thus, IGF-1 and exercise activates both IGF1R and IR in the heart, and IGF1R- and IR-mediated signals may serve redundant roles in the hypertrophic responses of the heart to exercise training.

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:Insulin-like growth factor 1 (IGF1) promotes a physiological type of cardiac hypertrophy and has therapeutic effects in heart disease. Here, we report the relationship of IGF1 to GATA4, an essential transcription factor in cardiac hypertrophy and cell survival. In cultured neonatal rat ventricular myocytes, we compared the responses to IGF1 (10 nmol/liter) and phenylephrine (PE, 20 μmol/liter), a known GATA4 activator, in concentrations promoting a similar extent of hypertrophy. IGF1 and PE both increased nuclear accumulation of GATA4 and phosphorylation at Ser(105) (PE, 2.4-fold; IGF1, 1.8-fold; both, p < 0.05) and increased GATA4 DNA binding activity as indicated by ELISA and by chromatin IP of selected promoters. Although IGF1 and PE each activated GATA4 to the same degree, GATA4 knockdown by RNA interference only blocked hypertrophy by PE but not by IGF1. PE induction of a panel of GATA4 target genes (Nppa, Nppb, Tnni3, Myl1, and Acta1) was inhibited by GATA4 knockdown. In contrast, IGF1 regulated only Acta1 in a GATA4-dependent fashion. Consistent with the in vitro findings, Gata4 haploinsufficiency in mice did not alter cardiac structure, hyperdynamic function, or antifibrotic effects induced by myocardial overexpression of the IGF1 receptor. Our data indicate that GATA4 is activated by the IGF1 pathway, but although it is required for responses to pathological stimuli, it is not necessary for the effects of IGF1 on cardiac structure and function.

Project description:Cardiac hypertrophy is the result of responses to various physiological or pathological stimuli. Recently, we showed that polycystin-1 participates in cardiomyocyte hypertrophy elicited by pressure overload and mechanical stress. Interestingly, polycystin-1 knockdown does not affect phenylephrine-induced cardiomyocyte hypertrophy, suggesting that the effects of polycystin-1 are stimulus-dependent. In this study, we aimed to identify the role of polycystin-1 in insulin-like growth factor-1 (IGF-1) signaling in cardiomyocytes. Polycystin-1 knockdown completely blunted IGF-1-induced cardiomyocyte hypertrophy. We then investigated the molecular mechanism underlying this result. We found that polycystin-1 silencing impaired the activation of the IGF-1 receptor, Akt, and ERK1/2 elicited by IGF-1. Remarkably, IGF-1-induced IGF-1 receptor, Akt, and ERK1/2 phosphorylations were restored when protein tyrosine phosphatase 1B was inhibited, suggesting that polycystin-1 knockdown deregulates this phosphatase in cardiomyocytes. Moreover, protein tyrosine phosphatase 1B inhibition also restored IGF-1-dependent cardiomyocyte hypertrophy in polycystin-1-deficient cells. Our findings provide the first evidence that polycystin-1 regulates IGF-1-induced cardiomyocyte hypertrophy through a mechanism involving protein tyrosine phosphatase 1B.

Project description:Background: Pathological cardiac hypertrophy is commonly associated with upregulation of fetal genes, fibrosis, cardiac dysfunction and leads to heart failure. Previous studies demonstrated that gastrodin (GAS) inhibited cardiac hypertrophy and thus improved cardiac function. However, the theraputic targets by which GAS regulates in the regression of cardiac hypertrophy has not been well elucidated yet. Methods: A mouse model of myocardial hypertrophy was estavlished by angiotensin II (Ang II) induction, then treated with GAS (0, 5 or 50 mg/kg/d) combined with the sham-operated controls. Heart samples from each dose group were collected for the next RNA sequencing.Through bioinformatics analysis, the key differentially expressed genes (DEG) involved in the recovery of cardiac function were identidied. They were further confirmed by quantitative real-time PCR (qRT-PCR) and western blotting in neonatal rat cardiomyocytes (NRCMs). Results: We identified 620 up-regulated and 87 down-regulated DEGs induced by Ang II, of which the expression patterns of 58 and 146 genes were reversed by low-dose and high-dose GAS, respectively. These reversed DEGs are mainly enriched in biological processs of regulation of Ras protein signal transduction, heart contraction, covalent chromatin modification, glucose metabolism and positive regulation of cell cycle. Among them, insulin-like growth factor type 2 (Igf2) gene, which was highly reversed and down-regulated by GAS, served as the core gene linking energy metabolism, immune regulation and system development. Subsequent functional verification demonstrated that the system of Igf2 and its receptor Igf2r is one of the targets of GAS in the treatment of cardiac hypertrophy, and knocking out Igf2r can protect NRCM from cardiac hypertrophy. Conclusions: Taken together, we, for the first time, identified Igf2/Igf2r as a therapeutic target influenced by GAS in the pharmacological intervention of cardiac hypertrophy

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:Pathological cardiac hypertrophy is commonly associated with an upregulation of fetal genes, fibrosis, cardiac dysfunction, and heart failure. Previous studies have demonstrated that gastrodin (GAS) exerts cardioprotective action in the treatment of cardiac hypertrophy. However, the mechanism by which GAS protects against cardiac hypertrophy is yet to be elucidated. A mouse model of myocardial hypertrophy was established using an angiotensin II (Ang II) induction. GAS (5 or 50 mg/kg/d) was orally administered every day starting 7 days prior to the Ang II infusion combined with sham-operated controls. Heart samples from each group were collected for RNA sequencing. Using bioinformatics analysis, the key differentially expressed genes (DEGs) that are involved in reversing cardiac function were identified. Through bioinformatics analysis, the key DEGs that are involved in GAS's inhibition of Ang II-induced abnormal gene expression within the heart were identified. This was further validated using quantitative real-time PCR and Western blotting in neonatal rat cardiomyocytes (NRCMs). Oral administration of GAS significantly suppressed the Ang II-induced increase in heart size and heart weight to body weight. Furthermore, pretreatment of the NRCMs with GAS led to a dose-dependent inhibition of Ang II-induced increases in Nppb mRNA expression. We identified 620 upregulated and 87 downregulated Ang II-induced DEGs II, among which the expression patterns of 58 and 146 genes were inverted by low-dose and high-dose GAS, respectively. These inverted DEGs were found to be mainly enriched in the biological processes of regulation of Ras protein signal transduction, heart contraction, covalent chromatin modification, glucose metabolism, and positive regulation of cell cycle. Among them, the insulin-like growth factor type 2 (Igf2) gene, which was found to be highly reversed and downregulated by GAS, served as a core gene linking energy metabolism, immune regulation, and systemic development. Subsequent functional verification demonstrated that IGF2, and its receptor IGF2R, is one of the targets of GAS that helps protect against cardiac hypertrophy. Taken together, we have identified, for the first time, IGF2/IGF2R as a potential target influenced by GAS in the prevention of cardiac hypertrophy.

Project description:Vascular endothelial growth factor-receptors (VEGF-Rs) are pivotal regulators of vascular development, but a specific role for these receptors in the formation of heart valves has not been identified. We took advantage of small molecule inhibitors of VEGF-R signaling and showed that blocking VEGF-R signaling with receptor selective tyrosine kinase inhibitors, PTK 787 and AAC 787, from 17-21 hr post-fertilization (hpf) in zebrafish embryos resulted in a functional and structural defect in cardiac valve development. Regurgitation of blood between the two chambers of the heart, as well as a loss of cell-restricted expression of the valve differentiation markers notch 1b and bone morphogenetic protein-4 (bmp-4), was readily apparent in treated embryos. In addition, microangiography revealed a loss of a definitive atrioventricular constriction in treated embryos. Taken together, these data demonstrate a novel function for VEGF-Rs in the endocardial endothelium of the developing cardiac valve.

Project description:Aims: Autophagy is a catabolic process required for the maintenance of cardiac health. Insulin and insulin-like growth factor 1 (IGF-1) are potent inhibitors of autophagy and as such, one would predict that autophagy will be increased in the insulin-resistant/diabetic heart. However, autophagy is rather decreased in the hearts of diabetic/insulin-resistant mice. The aim of this study is to determine the contribution of IGF-1 receptor signaling to autophagy suppression in insulin receptor (IR)-deficient hearts. Results: Absence of IRs in the heart was associated with reduced autophagic flux, and further inhibition of autophagosome clearance reduced survival, impaired contractile function, and enhanced myocyte loss. Contrary to the in vivo setting, isolated cardiomyocytes from IR-deficient hearts exhibited unrestrained autophagy in the absence of insulin, whereas addition of insulin was able to suppress autophagy. To investigate the mechanisms involved in the maintenance of the responsiveness to insulin in IR-deficient hearts, we generated mice lacking both IRs and one copy of the IGF-1 receptor (IGF-1R) in cardiac cells and showed that these mice had increased autophagy. Innovation and Conclusion: This study unveils a new mechanism by which IR-deficient hearts can still respond to insulin to suppress autophagy, in part, through activation of IGF-1R signaling. This is a highly significant observation because it is the first to show that systemic hyperinsulinemia can suppress autophagy in IR-deficient hearts through IGF-1R signaling.

Project description:RNA m6A modification is the most widely distributed RNA methylation and is closely related to various pathophysiological processes. Although the benefit of regular exercise on the heart has been well recognized, the role of RNA m6A in exercise training and exercise-induced physiological cardiac hypertrophy remains largely unknown. Here, we show that endurance exercise training leads to reduced cardiac mRNA m6A levels. METTL14 is downregulated by exercise, both at the level of RNA m6A and at the protein level. In vivo, wild-type METTL14 overexpression, but not MTase inactive mutant METTL14, blocks exercise-induced physiological cardiac hypertrophy. Cardiac-specific METTL14 knockdown attenuates acute ischemia-reperfusion injury as well as cardiac dysfunction in ischemia-reperfusion remodeling. Mechanistically, silencing METTL14 suppresses Phlpp2 mRNA m6A modifications and activates Akt-S473, in turn regulating cardiomyocyte growth and apoptosis. Our data indicates that METTL14 plays an important role in maintaining cardiac homeostasis. METTL14 downregulation represents a promising therapeutic strategy to attenuate cardiac remodeling.