Gene Therapy in Heart Failure

Vinge, Leif Erik; Raake, Philip; Koch, Walter J.

doi:10.1161/circresaha.108.173195

Cited by 120 publications

(113 citation statements)

References 155 publications

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“…These studies emphasize the importance of cellular, small and large animal models as well as a broad understanding of cellular and molecular integrity of the target protein to translate novel therapeutic concepts into a clinical setup (for a more detailed summary of additional target for cardiac gene therapy please refer to further article elaborating these points 8,68,69 ).…”

Section: Clinical Implementationmentioning

confidence: 99%

“…Among those, genetically targeted interventions directed at molecular abnormalities within diseased cardiac cells emerged as a promising option to correct key pathologies at the site of origin. 8 The concept of cardiac gene therapy might therefore meet the needs of modern HF therapy and eventually be able to halt and even reverse the disease.…”

Section: Introductionmentioning

confidence: 99%

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Targeting S100A1 in heart failure

Ritterhoff

Most

2012

Gene Ther

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Heart failure (HF) is the common endpoint of many cardiovascular diseases with a 1-year survival rate of about 50% in advanced stages. Despite increasing survival rates in the past years, current standard therapeutic strategies are far away from being optimal. For this reason, the concept of cardiac gene therapy for the treatment of HF holds great potential to improve disease progression, as it specifically targets key pathologies of diseased cardiomyocytes (CM). The small calcium (Ca 2+ )-binding protein S100A1 presents a promising target for cardiac gene therapy, as it has been identified as a central regulator of cardiac performance and the Ca 2+ -driven network within CM. S100A1 was shown to regulate sarcoplasmic reticulum, sarcomere and mitochondrial function by modulating target protein activity. Furthermore, deranged S100A1 expression has been linked to HF in human ischemic and dilated cardiomyopathies as well as in various HF animal models. Proof-of-concept studies in small and large animal models as wells as in human failing CM could demonstrate feasibility and efficacy of S100A1 genetically targeted therapy. This review summarizes the developmental steps of S100A1 gene therapy for the implementation into first human clinical trials.

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Section: Clinical Implementationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Targeting S100A1 in heart failure

Ritterhoff

Most

2012

Gene Ther

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“…24 In consideration of the fact that GRK2 levels often increase before manifested clinical HF, 25 and normalize again with advanced b-adrenergic signaling and ventricular function, 26,27 GRK2 not only represents a potential biomarker of cardiac function, 28 but is also an attractive therapeutic target for HF treatment. 29,30 GRK2 and the adrenal chromaffin cell Beside its essential role in the desensitization process of myocardial GPCRs such as bARs, GRK2 is involved in the regulation of plasma catecholamine release from the adrenal gland and also by extensions of SNS ganglia. Specifically, the physiological function of adrenal a 2c ARs is to inhibit catecholamine release into the synaptic cleft, acting as a negative-feedback loop in this process.…”

Section: Grk2: a Nodal Culprit In Hf Grk2 And The Cardiomyocytementioning

confidence: 99%

“…Gene therapy constitutes a promising potential novel therapeutic strategy for direct manipulation of intracellular mechanisms in cardiac myocytes. 30 Concerning gene therapy, significant efforts have been undertaken to develop molecular tools such as mini-peptides/proteins, which can be used to inhibit protein or enzyme function, or RNA interference (small interfering RNA/microRNA) for downregulation of genes. Alternatively, gene transfer can be used to replace or supplement downregulated proteins or enzyme targets.…”

Section: Grk2: a Nodal Culprit In Hf Grk2 And The Cardiomyocytementioning

confidence: 99%

“…These approaches in combination with modern viral vectors and cardiac-specific promoters are all orchestrated to effectively target intracellular molecular signaling defects and render gene therapy a rather interesting tool in potentially complementing established HF therapies. 30 Of course, cardiac gene therapy is still in its clinical infancy and a lot of effort is put into further optimization, with the ultimate goal of correcting key underlying signaling abnormalities inside the failing cardiac myocyte. Below, we highlight one gene therapeutic strategy, GRK2 inhibition, and how this target may be utilized in established pharmacological approaches (bAR blockade), both aimed at intercepting Cardiac bAR signaling and regulation by GRK2.…”

Section: Grk2: a Nodal Culprit In Hf Grk2 And The Cardiomyocytementioning

confidence: 99%

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Targeting GRK2 by gene therapy for heart failure: benefits above β-blockade

et al. 2012

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Heart failure (HF) is a common pathological end point for several cardiac diseases. Despite reasonable achievements in pharmacological, electrophysiological and surgical treatments, prognosis for chronic HF remains poor. Modern therapies are generally symptom oriented and do not currently address specific intracellular molecular signaling abnormalities. Therefore, new and innovative therapeutic approaches are warranted and, ideally, these could at least complement established therapeutic options if not replace them. Gene therapy has potential to serve in this regard in HF as vectors can be directed toward diseased myocytes and directly target intracellular signaling abnormalities. Within this review, we will dissect the adrenergic system contributing to HF development and progression with special emphasis on G-protein-coupled receptor kinase 2 (GRK2). The levels and activity of GRK2 are increased in HF and we and others have demonstrated that this kinase is a major molecular culprit in HF. We will cover the evidence supporting gene therapy directed against myocardial as well as adrenal GRK2 to improve the function and structure of the failing heart and how these strategies may offer complementary and synergistic effects with the existing HF mainstay therapy of b-adrenergic receptor antagonism.

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Model‐specific selection of molecular targets for heart failure gene therapy

Katz

Fargnoli

Tomasulo

et al. 2011

The Journal of Gene Medicine

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Heart failure (HF) is a complex multifaceted problem of abnormal ventricular function and structure. In recent years, new information has been accumulated allowing for a more detailed understanding of the cellular and molecular alterations that are the underpinnings of diverse causes of HF, including myocardial ischemia, pressure-overload, volume-overload or intrinsic cardiomyopathy. Modern pharmacological approaches to treat HF have had a significant impact on the course of the disease, although they do not reverse the underlying pathological state of the heart. Therefore gene-based therapy holds a great potential as a targeted treatment for cardiovascular diseases. Here, we survey the relative therapeutic efficacy of genetic modulation of β-adrenergic receptor signaling, Ca2+ handling proteins and angiogenesis in the most common extrinsic models of HF.

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Gene Therapy in Heart Failure

Cited by 120 publications

References 155 publications

Targeting S100A1 in heart failure

Targeting S100A1 in heart failure

Targeting GRK2 by gene therapy for heart failure: benefits above β-blockade

Model‐specific selection of molecular targets for heart failure gene therapy

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