Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0018801 (heart failure)
72,216 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

GRKs critically regulate betaAR signaling via receptor phosphorylation and the triggering of desensitization. In the heart, betaARs control the chronotropic, lusitropic, and inotropic responses to the catecholamine neurotransmitters, norepinephrine and epinephrine. Signaling through cardiac betaARs is significantly impaired in many cardiovascular disorders, including congestive heart failure. betaARK1 (also known as GRK2) is the most abundant GRK in the heart, and it is increased in several cardiovascular diseases associated with impaired cardiac signaling and function, suggesting that this molecule could have pathophysiological relevance in the setting of heart failure. The ability to manipulate the mouse genome has provided a powerful tool to study the physiological implications of altering GRK activity and expression in the heart. Recent studies in several different mouse models have demonstrated that betaARK1 plays a key role not only in the regulation of myocardial signaling, but also in cardiac function and development. Moreover, studies have shown that targeting the activity of GRKs, especially betaARK1, appears to be a novel therapeutic strategy for the treatment of the failing heart. Gene therapy technology makes it possible, beyond what is possible in the mouse, to directly test in larger animals whether betaARK1 inhibition in the setting of disease will improve the function of the compromised heart, and this methodology has also lead to compelling results. These genetic approaches or the development of small molecule inhibitors of betaARK1 and GRK activity may advance therapeutic options for heart disease.
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PMID:Transgenic mice targeting the heart unveil G protein-coupled receptor kinases as therapeutic targets. 1509 Feb

Heart failure (HF) represents one of the leading causes of morbidity and mortality in developed nations today. Although this disease process represents a final common endpoint for several entities, including hypertension, coronary artery disease, and cardiomyopathy, a predominant characteristic of end-stage HF is an altered beta-adrenergic receptor signaling cascade. In the heart, beta-adrenergic receptors (beta ARs), members of the superfamily of G-protein-coupled receptors (GPCRs), modulate cardiac function by controlling chronotropic, inotropic, and lusitropic responses to catecholamines of the sympathetic nervous system. In HF, beta ARs are desensitized and downregulated in a maladaptive response to chronic stimulation. This process is largely mediated by G-protein-coupled receptor kinases (GRKs), which phosphorylate GPCRs leading to functional uncoupling. The most abundant cardiac GRK, known as GRK2 or beta AR kinase 1 (beta ARK1), is increased in human HF, and has been implicated in the pathogenesis of dysfunctional cardiac beta AR signaling. The association of beta ARs and GRKs with impaired cardiac function has been extensively studied using transgenic mouse models, which have demonstrated that beta ARK1 plays a vital role in the regulation of myocardial beta AR signaling. These findings have caused beta ARs and GRKs to be regarded as potential therapeutic targets, and gene therapy strategies have been used to manipulate the beta AR signaling pathway in myocardium, leading to improved function in the compromised heart. Ultimately, these genetic modifications of the heart may represent new potential therapies for human HF.
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PMID:Genetic manipulation of myocardial beta-adrenergic receptor activation and desensitization. 1524 31

Heart failure affects 23 million people worldwide and results from cardiac dysfunction characterized by decreased responsiveness to beta-adrenergic stimulation. A recent publication by W.J. Koch and colleagues highlights evidence for targeted beta-adrenergic receptor kinase (betaARK1) inhibition by gene transfer to improve contractile function and beta-adrenergic responsiveness in failing human myocardium. This proof-of-concept study has great importance for future heart failure therapy because it provides evidence for the therapeutic effectiveness of betaARK1 inhibition in failing human myocardium.
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PMID:Hope for a broken heart? 1545 Jul 36

Heart failure is a leading cause of hospitalization worldwide. No major significant improvements in prognosis have been achieved for heart failure over the last several decades despite advances in disease management. Heart failure itself represents a final common endpoint for several disease entities, including hypertension and coronary artery disease. On a molecular level, certain biochemical features remain common to failing myocardium. Among these are alterations in the beta-adrenergic receptor (beta-AR) signaling cascade. Recent advances in transgenic and gene therapy techniques have presented novel therapeutic strategies for management of heart failure via genetic manipulation of beta-AR signaling including the targeted inhibition of the beta-AR kinase (betaARK1 or GRK2). In this review, we will discuss the beta-AR signaling changes that accompany heart failure as well as corresponding therapeutic strategies. We will then review the evidence from transgenic mouse work supporting the use of beta-AR manipulation in the failing heart and more recent in vivo applications of gene therapy directed at reversing or preventing heart failure.
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PMID:Genetic and phenotypic targeting of beta-adrenergic signaling in heart failure. 1552 62

G-protein-coupled receptor kinases (GRKs) are involved in cardiac hypertrophy and failure. But their temporal expression and cellular localization during the development of hypertrophy and its transition to failure remains to be investigated. In this study, we determined the expression and subcellular distribution of GRK2, GRK3, GRK5, and GRK6 in cardiac myocytes of 2- to 24-month-old spontaneously hypertensive heart failure (SHHF) rats. GRK2 increased in the intercalated disks in 6-, 12-, and 24-month-old SHHF rats, although total expression remained relatively constant from 2 to 24 months in both SHHF and normotensive rats. GRK3 expression progressively increased in 6-, 12-, and 24-month-old SHHF rats and was significantly higher than in age-matched controls. Immunolabeling of GRK3 showed a typical pattern of cross-striations that colocalized with alpha-actinin and G(alphas) at Z-lines in both SHHF and control rats. GRK5 expression showed no change from 2 to 24 months in both SHHF and normotensive rats. Confocal analysis revealed nuclear translocation of GRK5 in myocytes of SHHF rats. GRK6 had a striated pattern colocalized with alpha-actinin at Z-lines in the cytoplasm and was also present in the intercalated disks of cardiac myocytes from both SHHF and control rats. GRK6 expression increased in 12- and 24-month-old SHHF rats and was significantly higher than in age-matched controls. GRK6 labeling was reduced at the intercalated disks, but increased in the cytoplasm of cardiac myocytes from SHHF rats compared to age-matched controls. The increased expression of GRK3 and GRK6 and subcellular redistribution of GRK2, GRK5, and GRK6 in SHHF rats may be involved in abnormal remodeling of cardiac myocytes in hypertensive hypertrophy and failure.
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PMID:Myocardial expression and redistribution of GRKs in hypertensive hypertrophy and failure. 1558 34

To examine the mechanisms of changes in beta-adrenergic signal transduction in heart failing due to volume overload, we studied the status of beta-adrenoceptors (beta-ARs), G protein-coupled receptor kinase (GRK), and beta-arrestin in heart failure due to aortocaval shunt (AVS). Heart failure in rats was induced by creating AVS for 16 wk, and beta-AR binding, GRK activity, as well as their protein content, and mRNA levels were determined in both left and right ventricles. The density and protein content for beta1-ARs, unlike those for beta2-ARs, were increased in the failing hearts. Furthermore, protein contents for GRK isoforms and beta-arrestin-1 were decreased in membranous fractions and increased in cytosolic fractions from the failing hearts. On the other hand, steady-state mRNA levels for beta1-ARs and GRK2, as well as protein content for Gbetagamma-subunits, did not change in the failing heart. Basal cardiac function was depressed; however, both in vivo and ex vivo positive inotropic responses of the failing hearts to isoproterenol were augmented. Treatment of AVS animals with imidapril (1 mg.kg(-1).day(-1)) or losartan (20 mg.kg(-1).day(-1)) retarded the progression of heart failure; partially prevented changes in beta1-ARs, GRKs, and beta-arrestin-1 in the failing myocardium; and attenuated the increase in positive inotropic effect of isoproterenol. These results indicate that upregulation of beta1-ARs is associated with subcellular redistribution of GRKs and beta-arrestin-1 in the failing heart due to volume overload. Furthermore, attenuation of alterations in beta-adrenergic system by imidapril or losartan may be due to blockade of the renin-angiotensin system in the AVS model of heart failure.
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PMID:Upregulation of beta-adrenergic receptors in heart failure due to volume overload. 1573 91

The actions of G-protein coupled receptor kinases (GRKs) critically regulate beta-adrenergic receptor (betaAR) signalling. In the cardiovascular system, the betaAR signalling pathway controls important responses of the heart such as the ability to contract (inotropy), the ability to contract faster (chronotropy) and the ability to relax (lusotropy). The observation that the betaAR kinase (betaARK1, also known as GRK2), the most abundant GRK in the heart, is increased in cardiovascular disease associated with impaired cardiac function, suggests that this molecule could have pathophysiological relevance in the setting of heart failure. Technological advances in the genetic engineering of mice have provided a powerful tool to study the physiological implications of altering GRK activity and expression in the heart. Recent studies have demonstrated that betaARK1 plays a key role in not only the regulation of myocardial signalling, but also in cardiac function and development. Importantly, targeting the activity of GRKs, and betaARK1 in particular, appears to represent a novel therapeutic strategy for the treatment of the failing heart. At present, gene therapy modalities are being tested which inhibit the activity of betaARK1 in the heart. This technology makes it possible to test directly whether betaARK1 inhibition in the setting of heart disease will improve the function of the compromised heart. Thus, these genetic approaches or the development of small molecule inhibitors of GRK activity, may lead to novel therapeutic approaches for cardiovascular disease.
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PMID:Therapeutic potential of G-protein coupled receptor kinases in the heart. 1599 14

Myocardial infarction (MI) represents an enormous clinical challenge as loss of myocardium due to ischemic injury is associated with compromised left ventricular (LV) function often leading to acute cardiac decompensation or chronic heart failure. S100A1 was recently identified as a positive inotropic regulator of myocardial contractility in vitro and in vivo. Here, we explore the strategy of myocardial S100A1 gene therapy either at the time of, or 2 h after, MI to preserve global heart function. Rats underwent cryothermia-induced MI and in vivo intracoronary delivery of adenoviral transgenes (4 x 10(10) pfu). Animals received saline (MI), the S100A1 adenovirus (MI/AdS100A1), a control adenovirus (MI/AdGFP), or a sham operation. S100A1 gene delivery preserved global in vivo LV function 1 week after MI. Preservation of LV function was due mainly to S100A1-mediated gain of contractility of the remaining, viable myocardium since contractile parameters and Ca(2+) transients of isolated MI/AdS100A1 myocytes were significantly enhanced compared to myocytes isolated from both MI/AdGFP and sham groups. Moreover, S100A1 gene therapy preserved the cardiac beta-adrenergic inotropic reserve, which was associated with the attenuation of GRK2 up-regulation. Also, S100A1 overexpression reduced cardiac hypertrophy 1 week post-MI. Overall, our data indicate that S100A1 gene therapy provides a potential novel treatment strategy to maintain contractile performance of the post-MI heart.
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PMID:S100A1 gene therapy preserves in vivo cardiac function after myocardial infarction. 1616 14

We previously found that a canine model of selective surgical ventricular denervation (VD), which does not permit increased sympathetic tone during the pathogenesis of heart failure (HF), tolerated the development of HF better than controls. To investigate the cellular mechanisms, we examined cellular contraction and L-type Ca(2+) channel currents (I(Ca)) and their responses to beta-adrenergic receptor (beta-AR) stimulation in left ventricular myocytes from 1) control, 2) VD, 3) HF induced by rapid pacing, and 4) HF induced in VD (VD-HF) dogs. The magnitude of myocyte contraction and rate of relaxation in VD were similar to control but were depressed in both HF and VD-HF. These changes were associated with reduced protein expression of sarcoplasmic reticulum Ca(2+)-ATPase (SERCA2a) and protein kinase A phosphorylated phospholamban (PLB), which was reduced in HF, but essentially abolished in VD-HF. beta-AR kinase (GRK2) was increased in HF but reduced in VD-HF. Basal I(Ca) density did not differ among control, VD, and HF groups, but VD-HF myocytes showed a markedly reduced I(Ca) density (approximately 40%). Compared to controls, the sensitivity of I(Ca) to isoproterenol (ISO), was significantly higher in VD, but reduced in HF. While I(Ca) responses to ISO in VD-HF were maintained at control levels, the amplitude of the ISO-stimulated I(Ca) was significantly smaller (approximately 50%) compared with HF myocytes. The relative decrease in Ca(2+) influx due to downregulation of I(Ca) density may contribute to the cardioprotective effects in VD-HF hearts by preventing Ca(2+) overload during the development of HF. These findings, in combination with the virtual abolition of phosphorylated PLB in VD-HF and the decrease in GRK2, may explain, in part, why VD dogs tolerate the development of HF better than control dogs.
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PMID:Down regulation of the L-type Ca2+ channel, GRK2, and phosphorylated phospholamban: protective mechanisms for the denervated failing heart. 1660 Feb 89

Phosphorylation of the agonist-activated form of G-protein-coupled receptors (GPCRs) by a protein kinase from the G-protein-coupled receptor kinase (GRK) family initiates, with arrestin proteins, a negative feedback process known as desensitization. Because these receptors are involved in so many vital functions, it seems likely that disorders affecting GRK- or arrestin-mediated regulation of GPCRs would contribute to, if not engender, disease. Traditionally, it is believed that the desensitization process protects the cell against an overstimulation; however, in certain situations, this process is maladjusted and participes in disease progression. For example, in Oguchi disease, excessive rhodopsin stimulation due to a functional loss of GRK1 or arrestin 1 leads to light sensitization and stationary night blindness. Also, transgenic mice with vascular smooth muscle-targeted overexpression of GRK2 showed an elevated resting blood pressure, suggesting that increase in GRK2 level in humans is involved in hypertension associated with a decreased effect of beta-adrenergic receptor-mediated vasorelaxation. The restoration of normal GPCR function in modulating the desensitization process has been successfully demonstrated in animal models of heart failure, which indicates that targeting GRKs or arrestins may open a novel therapeutic strategy in human diseases with GPCR dysregulation. However, the few effective pharmacological compounds in this domain currently preclude human clinical tests.
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PMID:[GRKs and arrestins: the therapeutic pathway?]. 1668 24


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