Your search keyword '"Rabinowitz, Joseph"' showing total 9 results

1. MCARD-Mediated Gene Transfer of GRK2 Inhibitor in Ovine Model of Acute Myocardial Infarction

Author

Swain, JaBaris D., Fargnoli, Anthony S., Katz, Michael G., Tomasulo, Catherine E., Sumaroka, Marina, Richardville, Kyle C., Koch, Walter J., Rabinowitz, Joseph E., and Bridges, Charles R.

Published

2013

2. Realizing the promise of gene therapy through collaboration and partnering: Prizer's view.

Author

Tretiakova, Anna P., Murphy, John E., Binks, Michael, Mensah, Paul, Rabinowitz, Joseph, McCarty, Douglas M., Beaverson, Katherine, MacLeod, Molly, LaRosa, Gregory, and Cheng, Seng H.

Subjects

GENE therapy, GENETIC engineering, GENOME editing, TREATMENT of Duchenne muscular dystrophy

Abstract

A research article is presented that discusses the promise of gene therapy through collaboration and partnering. The article is produced in collaboration with the drug corporation Pfizer. Topics discussed include Pfizer's focus upon single-gene defects and hematologic disease, efforts to find a cure for Duchenne muscular dystrophy, and research aimed at improving organ function.

Published

2019

3. Comparative Cardiac Gene Delivery of Adeno-Associated Virus Serotypes 1–9 reveals that AAV6 Mediates the Most Efficient Transduction in Mouse Heart.

Author

Zincarelli, Carmela, Soltys, Stephen, Rengo, Giuseppe, Koch, Walter J., and Rabinowitz, Joseph E.

Subjects

MICE, ADENOVIRUSES, ADENOVIRUS diseases, GENE therapy, SEROTYPES, PULMONARY artery

Abstract

Cardiac gene transfer is an attractive tool for developing novel heart disease treatments. Adeno-associated viral (AAV) vectors are widely used to mediate transgene expression in animal models and are being evaluated for human gene therapy. However, it is not clear which serotype displays the best cardiac tropism. Therefore, we curried out this study to directly compare AAV serotypes 1–9 heart transduction efficiency after indirect intracoronary injection. AAV-cytomegalovirus immediate early enhancer promoter (CMV)-luciferase serotypes 1–9 were injected in the left ventricular cavity of adult mice, after cross-clamping the ascending aorta and pulmonary artery. An imaging system was used to visualize luciferase expression at 3, 7, 21, 70, and 140 days postinjection. Echocardiography was performed to evaluate cardiac function on day 140. At the end of the study, luciferase enzyme activity and genome copies of the different AAV serotypes were assessed in several tissues and potential AAV immunogenicity was evaluated on heart sections by staining for macrophage and lymphocyte antigens. Among AAV serotypes 1–9, AAV6 showed the best capability of achieving high transduction levels in the myocardium in a tissue-specific manner, whereas the other serotypes had less cardiac transduction and more extracardiac expression, especially in the liver. Importantly, none of the serotypes tested with this marker gene affected cardiac function nor was associated with inflammation. [ABSTRACT FROM AUTHOR]

Published

2010

4. Cross-Dressing the Virion: the Transcapsidation of Adeno-Associated Virus Serotypes Functionally Defines Subgroups.

Author

Rabinowitz, Joseph E., Bowles, Dawn E., Faust, Susan M., Ledford, Julie G., Cunningham, Scott E., and Samulski, R. Jude

Subjects

*ADENOVIRUSES, *GENETICS, *PROTEINS, *VIRUSES, *GENE transfection, *GENE therapy

Abstract

For all adeno-associated virus (AAV) serotypes, 60 monomers of the Vp1, Vp2, and Vp3 structural proteins assemble via an unknown mechanism to form an intact capsid. In an effort to better understand the properties of the capsid monomers and their role in viral entry and infection, we evaluated whether monomers from distinct serotypes can be mixed to form infectious particles with unique phenotypes. This transcapsidation approach consisted of the transfection of pairwise combinations of AAV serotype 1 to 5 helper plasmids to produce mosaic capsid recombinant AAV (rAAV). All ratios (19:1, 3:1, 1:1, 1:3, and 1:19) of these mixtures were able to replicate the green fluorescent protein transgene and to produce capsid proteins. A high-titer rAAV was obtained with mixtures that included either serotype 1, 2, or 3, whereas an rAAV of intermediate titer was obtained from serotype 5 mixtures. Only mixtures containing the AAV4 capsid exhibited reduced packaging capacity. The binding profiles of the mixed-virus preparations to either heparin sulfate (HS) or mucin agarose revealed that only AAV3-AAV5 mixtures at the 3:1 ratio exhibited duality in binding. All other mixtures displayed either an abrupt shift or a gradual alteration in the binding profile to the respective ligand upon increase of a capsid component that conferred either HS or mucin binding. The transduction of cell lines was used to further evaluate the phenotypes of these transcapsidated virions. Three transduction profiles were observed: (i) small to no change regardless of ratio, (ii) a gradual increase in transduction consistent with titration of a second capsid component, or (iii) an abrupt increase in transduction (threshold effect) dependent on the specific ratios used. Interestingly, an unexpected synergistic effect in transduction was observed when AAV1 helper constructs were combined with type 2 or type 3 recipient helpers. Further studies determined that at least two components contributed to this observed synergy: (i) heparin-mediated binding from AAV2 and (ii) an unidentified enhancement activity from AAV1 structural proteins. Using this procedure of mixing different AAV helper plasmids to generate "cross-dressed" AAV virions, we propose an additional means of classifying new AAV serotypes into subgroups based on functional approaches to analyze AAV capsid assembly, receptormediated binding, and virus trafficking. Exploitation of this approach in generating custom-designed AAV vectors should be of significant value to the field of gene therapy. [ABSTRACT FROM AUTHOR]

Published

2004

5. The next step in gene delivery: Molecular engineering of adeno-associated virus serotypes

Author

Wang, Jinhui, Faust, Susan M., and Rabinowitz, Joseph E.

Subjects

*ADENOVIRUSES, *SEROTYPES, *DRUG delivery systems, *DNA viruses, *IMMUNE system, *MUTAGENESIS, *GENE therapy

Abstract

Abstract: Delivery is at the heart of gene therapy. Viral DNA delivery systems are asked to avoid the immune system, transduce specific target cell types while avoiding other cell types, infect dividing and non-dividing cells, insert their cargo within the host genome without mutagenesis or to remain episomal, and efficiently express transgenes for a substantial portion of a lifespan. These sought-after features cannot be associated with a single delivery system, or can they? The Adeno-associated virus family of gene delivery vehicles has proven to be highly malleable. Pseudotyping, using AAV serotype 2 terminal repeats to generate designer shells capable of transducing selected cell types, enables the packaging of common genomes into multiple serotypes virions to directly compare gene expression and tropism. In this review the ability to manipulate this virus will be examined from the inside out. The influence of host cell factors and organism biology including the immune response on the molecular fate of the viral genome will be discussed as well as differences in cellular trafficking patterns and uncoating properties that influence serotype transduction. Re-engineering the prototype vector AAV2 using epitope insertion, chemical modification, and molecular evolution not only demonstrated the flexibility of the best-studied serotype, but now also expanded the tool kit for molecular modification of all AAV serotypes. Current AAV research has changed its focus from examination of wild-type AAV biology to the feedback of host cell/organism on the design and development of a new generation of recombinant AAV delivery vehicles. This article is part of a Special Section entitled “Special Section: Cardiovascular Gene Therapy”. [Copyright &y& Elsevier]

Published

2011

6. Phase 1 Gene Therapy for Duchenne Muscular Dystrophy Using a Translational Optimized AAV Vector.

Author

Bowles, Dawn E, McPhee, Scott WJ, Li, Chengwen, Gray, Steven J, Samulski, Jade J, Camp, Angelique S, Li, Juan, Wang, Bing, Monahan, Paul E, Rabinowitz, Joseph E, Grieger, Joshua C, Govindasamy, Lakshmanan, Agbandje-McKenna, Mavis, Xiao, Xiao, and Samulski, R Jude

Subjects

*GENE therapy, *TREATMENT of Duchenne muscular dystrophy, *GENETIC transformation, *ADENO-associated virus, *GENETIC mutation, *GENETIC transduction, *IMMUNE response, *CLINICAL trials, *PHYSIOLOGY

Abstract

Efficient and widespread gene transfer is required for successful treatment of Duchenne muscular dystrophy (DMD). Here, we performed the first clinical trial using a chimeric adeno-associated virus (AAV) capsid variant (designated AAV2.5) derived from a rational design strategy. AAV2.5 was generated from the AAV2 capsid with five mutations from AAV1. The novel chimeric vector combines the improved muscle transduction capacity of AAV1 with reduced antigenic crossreactivity against both parental serotypes, while keeping the AAV2 receptor binding. In a randomized double-blind placebo-controlled phase I clinical study in DMD boys, AAV2.5 vector was injected into the bicep muscle in one arm, with saline control in the contralateral arm. A subset of patients received AAV empty capsid instead of saline in an effort to distinguish an immune response to vector versus minidystrophin transgene. Recombinant AAV genomes were detected in all patients with up to 2.56 vector copies per diploid genome. There was no cellular immune response to AAV2.5 capsid. This trial established that rationally designed AAV2.5 vector was safe and well tolerated, lays the foundation of customizing AAV vectors that best suit the clinical objective (e.g., limb infusion gene delivery) and should usher in the next generation of viral delivery systems for human gene transfer. [ABSTRACT FROM AUTHOR]

Published

2012

7. S100A1 Genetically Targeted Therapy Reverses Dysfunction of Human Failing Cardiomyocytes

Author

Brinks, Henriette, Rohde, David, Voelkers, Mirko, Qiu, Gang, Pleger, Sven T., Herzog, Nicole, Rabinowitz, Joseph, Ruhparwar, Arjang, Silvestry, Scott, Lerchenmüller, Carolin, Mather, Paul J., Eckhart, Andrea D., Katus, Hugo A., Carrel, Thierry, Koch, Walter J., and Most, Patrick

Subjects

*HEART failure, *GENE targeting, *HEART cells, *GENETIC transformation, *MITOCHONDRIA, *DISEASE susceptibility, *SARCOPLASMIC reticulum, *BETA adrenoceptors, *GENE therapy

Abstract

Objectives: This study investigated the hypothesis whether S100A1 gene therapy can improve pathological key features in human failing ventricular cardiomyocytes (HFCMs). Background: Depletion of the Ca2+-sensor protein S100A1 drives deterioration of cardiac performance toward heart failure (HF) in experimental animal models. Targeted repair of this molecular defect by cardiac-specific S100A1 gene therapy rescued cardiac performance, raising the immanent question of its effects in human failing myocardium. Methods: Enzymatically isolated HFCMs from hearts with severe systolic HF were subjected to S100A1 and control adenoviral gene transfer and contractile performance, calcium handling, signaling, and energy homeostasis were analyzed by video-edge-detection, FURA2-based epifluorescent microscopy, phosphorylation site-specific antibodies, and mitochondrial assays, respectively. Results: Genetically targeted therapy employing the human S100A1 cDNA normalized decreased S100A1 protein levels in HFCMs, reversed both contractile dysfunction and negative force-frequency relationship, and improved contractile reserve under beta-adrenergic receptor (β-AR) stimulation independent of cAMP-dependent (PKA) and calmodulin-dependent (CaMKII) kinase activity. S100A1 reversed underlying Ca2+ handling abnormalities basally and under β-AR stimulation shown by improved SR Ca2+ handling, intracellular Ca2+ transients, diastolic Ca2+ overload, and diminished susceptibility to arrhythmogenic SR Ca2+ leak, respectively. Moreover, S100A1 ameliorated compromised mitochondrial function and restored the phosphocreatine/adenosine-triphosphate ratio. Conclusions: Our results demonstrate for the first time the therapeutic efficacy of genetically reconstituted S100A1 protein levels in HFCMs by reversing pathophysiological features that characterize human failing myocardium. Our findings close a gap in our understanding of S100A1''s effects in human cardiomyocytes and strengthen the rationale for future molecular-guided therapy of human HF. [Copyright &y& Elsevier]

Published

2011

8. Myocardial adeno-associated virus serotype 6-βARKct gene therapy improves cardiac function and normalizes the neurohormonal axis in chronic heart failure

Author

Carmela Zincarelli, Stephen Soltys, Joseph E. Rabinowitz, Anastasios Lymperopoulos, Walter J. Koch, Maria Donniacuo, Giuseppe Rengo, Rengo, Giuseppe, Lymperopoulos, Anastasio, Zincarelli, Carmela, Donniacuo, Maria, Soltys, Stephen, Rabinowitz, Joseph E., Koch, Walter J., Rengo, G., Lymperopoulos, A., Zincarelli, C., Donniacuo, M., Soltys, S., Rabinowitz, J. E., and Koch, W. J.

Subjects

medicine.disease_cause, Catecholamines, Neurohormone, Transgenes, Adeno-associated virus, Aldosterone, Metoprolol, Ultrasonography, Ventricular Remodeling, Dependovirus, Recombinant Protein, Dependoviru, Recombinant Proteins, medicine.anatomical_structure, Peptide, Cardiology, Catecholamine, Rats, Transgenic, Cardiology and Cardiovascular Medicine, medicine.drug, Cardiac function curve, medicine.medical_specialty, Adrenergic beta-Antagonists, Green Fluorescent Proteins, Gene delivery, Green Fluorescent Protein, Article, Contractility, Transgene, Gene therapy, Internal medicine, Physiology (medical), Receptors, Adrenergic, beta, medicine, Animals, Ventricular remodeling, Cardiac remodeling, Heart Failure, business.industry, Animal, Ventricular, Adrenergic beta-Antagonist, Genetic Therapy, medicine.disease, Rats, Disease Models, Animal, Ventricle, Heart failure, Chronic Disease, Rat, Peptides, business

Abstract

Background— The upregulation of G protein–coupled receptor kinase 2 in failing myocardium appears to contribute to dysfunctional β-adrenergic receptor (βAR) signaling and cardiac function. The peptide βARKct, which can inhibit the activation of G protein–coupled receptor kinase 2 and improve βAR signaling, has been shown in transgenic models and short-term gene transfer experiments to rescue heart failure (HF). This study was designed to evaluate long-term βARKct expression in HF with the use of stable myocardial gene delivery with adeno-associated virus serotype 6 (AAV6). Methods and Results— In HF rats, we delivered βARKct or green fluorescent protein as a control via AAV6-mediated direct intramyocardial injection. We also treated groups with concurrent administration of the β-blocker metoprolol. We found robust and long-term transgene expression in the left ventricle at least 12 weeks after delivery. βARKct significantly improved cardiac contractility and reversed left ventricular remodeling, which was accompanied by a normalization of the neurohormonal (catecholamines and aldosterone) status of the chronic HF animals, including normalization of cardiac βAR signaling. Addition of metoprolol neither enhanced nor decreased βARKct-mediated beneficial effects, although metoprolol alone, despite not improving contractility, prevented further deterioration of the left ventricle. Conclusions— Long-term cardiac AAV6-βARKct gene therapy in HF results in sustained improvement of global cardiac function and reversal of remodeling at least in part as a result of a normalization of the neurohormonal signaling axis. In addition, βARKct alone improves outcomes more than a β-blocker alone, whereas both treatments are compatible. These findings show that βARKct gene therapy can be of long-term therapeutic value in HF.

Published

2009

9. 1064. Haute Couture Vectors: Solving Clinical Problems with Custom Designed AAV Vectors.

Author

Bowles, Dawn E., Li, Chengwen, Monahan, Paul E., Rabinowitz, Joseph E., McKenna, Mavis, and Samulski, Jude

Subjects

*GENETIC vectors, *TRANSGENES, *GENE therapy, *NUCLEOTIDE sequence, *SEROTYPES

Abstract

Compelling evidence that therapeutic transgene levels can be achieved from adeno-associated virus (AAV) vectors has not been observed in any human gene therapy application to date. We show that AAV capsids can be tailored to solve such clinical problems and describe here a new generation of AAV vectors approved for use in clinical studies.The availability of capsid DNA sequences from AAV serotypes exhibiting elevated tissue transduction profiles, the absence of cross-neutralizing antibody between certain serotypes (e.g. AAV2 and AAV1), and the three-dimensional structure of the AAV2 capsid served as a roadmap for AAV2 capsid surface positions to change as well as replacement amino acid candidates in the generation of these new vectors.A subset of these rationally designed AAV2 capsid variants exhibited enhanced skeletal muscle transduction, diminished recognition by human sera, and the ability to overcome the presence of AAV2 neutralizing antibodies all without disrupting current AAV2 purification parameters. These chimeric AAV vector displayed identical viral yield as parent virus AAV2, vector stability, and long- term gene expression in vivo. Further engineering determined that the insertion of only one amino acid in the AAV2 capsid was responsible for both the phenotypes of skeletal muscle enhanced transduction as well as resistance to anti-AAV2 neutralizing antibodies. Validation of these chimeric AAV vectors in clinical trials is on-going and outcome should provide essential data required for testing in human disorders such as muscular dystrophy and hemophilia B.Notes: DEB and CL contributed equally to this work. Present addresses of DEB and JER: Department of Surgery, Duke University, DUMC, Durham, NC (DEB). Center for Translational Medicine, Thomas Jefferson University, Philadelphia, PA (JER).Molecular Therapy (2006) 13, S408–S408; doi: 10.1016/j.ymthe.2006.08.1162 [ABSTRACT FROM AUTHOR]

Published

2006