Your search keyword '"Thomas Wechsler"' showing total 5 results

1. ZFN-Mediated In Vivo Genome Editing Corrects Murine Hurler Syndrome

Author

Susan Tom, Kathleen Meyer, Kelly M. Podetz-Pedersen, Renee Cooksley, Michael C. Holmes, R. Scott McIvor, Russell Dekelver, Brenda Koniar, Michelle Rohde, Kanut Laoharawee, Scott Sproul, Chester B. Whitley, Susan St Martin, Robert Radeke, Li Ou, Yolanda Santiago, Thomas Wechsler, and Michelle J. Przybilla

Subjects

Male, medicine.medical_treatment, Genetic enhancement, Mucopolysaccharidosis I, Hematopoietic stem cell transplantation, 03 medical and health sciences, Mucopolysaccharidosis type I, Iduronidase, Mice, 0302 clinical medicine, Genome editing, lysosomal diseases, In vivo, Drug Discovery, Genetics, Medicine, Animals, Enzyme Replacement Therapy, Hurler syndrome, Molecular Biology, Gene, 030304 developmental biology, Glycosaminoglycans, Pharmacology, Gene Editing, 0303 health sciences, business.industry, Enzyme replacement therapy, Genetic Therapy, medicine.disease, gene therapy, Zinc Finger Nucleases, Lysosomal Storage Diseases, Disease Models, Animal, 030220 oncology & carcinogenesis, Cancer research, Molecular Medicine, Original Article, Female, business

Abstract

Mucopolysaccharidosis type I (MPS I) is a severe disease due to deficiency of the lysosomal hydrolase α-L-iduronidase (IDUA) and the subsequent accumulation of the glycosaminoglycans (GAG), leading to progressive, systemic disease and a shortened lifespan. Current treatment options consist of hematopoietic stem cell transplantation, which carries significant mortality and morbidity risk, and enzyme replacement therapy, which requires lifelong infusions of replacement enzyme; neither provides adequate therapy, even in combination. A novel in vivo genome-editing approach is described in the murine model of Hurler syndrome. A corrective copy of the IDUA gene is inserted at the albumin locus in hepatocytes, leading to sustained enzyme expression, secretion from the liver into circulation, and subsequent uptake systemically at levels sufficient for correction of metabolic disease (GAG substrate accumulation) and prevention of neurobehavioral deficits in MPS I mice. This study serves as a proof-of-concept for this platform-based approach that should be broadly applicable to the treatment of a wide array of monogenic diseases., In vivo genome editing following a single injection of ZFN and IDUA donor encoding AAV8 resulted in metabolic correction and neurological benefit in a murine model of MPS I. These results enable a currently open clinical trial to evaluate targeted genome engineering for MPS I in humans.

Published

2018

2. Dose-Dependent Prevention of Metabolic and Neurologic Disease in Murine MPS II by ZFN-Mediated In Vivo Genome Editing

Author

Kanut Laoharawee, R. Scott McIvor, Hoang Oanh Nguyen, Michelle Rohde, Robert Radeke, Tam T Nguyen, Michael C. Holmes, Li Ou, Kelly M. Podetz-Pedersen, Scott Sproul, Thomas Wechsler, Russell Dekelver, Chester B. Whitley, Susan St Martin, Susan Tom, and Kathleen Meyer

Subjects

0301 basic medicine, in vivo genome editing, Genetic enhancement, Gene Dosage, Iduronate Sulfatase, Pharmacology, Biology, law.invention, Mice, 03 medical and health sciences, Genome editing, law, Drug Discovery, Genetics, medicine, Animals, Mucopolysaccharidosis type II, Molecular Biology, Mucopolysaccharidosis II, Gene Editing, lysosomal disease, fungi, Gene Transfer Techniques, Iduronate-2-sulfatase, Zinc Fingers, Hunter syndrome, Enzyme replacement therapy, Endonucleases, medicine.disease, gene therapy, Zinc finger nuclease, zinc finger nuclease, Introns, Enzyme Activation, Disease Models, Animal, Phenotype, 030104 developmental biology, MPS II, albumin locus, Hepatocytes, Recombinant DNA, Molecular Medicine, Original Article, Energy Metabolism, Biomarkers, iduronate 2-sulfatase

Abstract

Mucopolysaccharidosis type II (MPS II) is an X-linked recessive lysosomal disorder caused by deficiency of iduronate 2-sulfatase (IDS), leading to accumulation of glycosaminoglycans (GAGs) in tissues of affected individuals, progressive disease, and shortened lifespan. Currently available enzyme replacement therapy (ERT) requires lifelong infusions and does not provide neurologic benefit. We utilized a zinc finger nuclease (ZFN)-targeting system to mediate genome editing for insertion of the human IDS (hIDS) coding sequence into a “safe harbor” site, intron 1 of the albumin locus in hepatocytes of an MPS II mouse model. Three dose levels of recombinant AAV2/8 vectors encoding a pair of ZFNs and a hIDS cDNA donor were administered systemically in MPS II mice. Supraphysiological, vector dose-dependent levels of IDS enzyme were observed in the circulation and peripheral organs of ZFN+donor-treated mice. GAG contents were markedly reduced in tissues from all ZFN+donor-treated groups. Surprisingly, we also demonstrate that ZFN-mediated genome editing prevented the development of neurocognitive deficit in young MPS II mice (6–9 weeks old) treated at high vector dose levels. We conclude that this ZFN-based platform for expression of therapeutic proteins from the albumin locus is a promising approach for treatment of MPS II and other lysosomal diseases., AAV-mediated in vivo delivery of ZFN and IDS donor resulted in site-specific gene insertion and dose-dependent IDS expression in a mouse model of MPS II. These results support a currently open clinical trial, the first ever in vivo human genome editing study to be conducted.

Published

2018

3. 485. ZFN-Mediated Liver-Targeting Gene Therapy Corrects Systemic and Neurological Disease of Mucopolysaccharidosis Type I

Author

Susan Tom, R. Scott McIvor, Russell Dekelver, Li Ou, Chester B. Whitley, Michael J. Przybilla, Thomas Wechsler, Robert Radeke, Michael C. Holmes, Kanut Laoharawee, Renee Cooksley, Amy Manning-Bog, Brenda L. Komar, Scott Sproul, Michelle Rohde, and Kelly M. Podetz-Pedersen

Subjects

0301 basic medicine, Pharmacology, Genetic enhancement, Transgene, Albumin, Wild type, Spleen, Enzyme replacement therapy, 030105 genetics & heredity, Biology, 03 medical and health sciences, Mucopolysaccharidosis type I, 0302 clinical medicine, medicine.anatomical_structure, In vivo, Drug Discovery, Immunology, Genetics, medicine, Molecular Medicine, Molecular Biology, 030217 neurology & neurosurgery

Abstract

Mucopolysaccharidosis type I (MPS I) is characterized by progressive neurodegeneration, and premature death (

Published

2016

4. 484. In Vivo Zinc-Finger Nuclease Mediated Iduronate-2-Sulfatase (IDS) Target Gene Insertion and Correction of Metabolic Disease in a Mouse Model of Mucopolysaccharidosis Type II (MPS II)

Author

Kanut Laoharawee, Michelle Rohde, Amy Manning-Bog, Li Ou, Susan Tom, R. Scott McIvor, Kelly M. Podetz-Petersen, Kathleen Meyer, Russell Dekelver, Thomas Wechsler, Robert Radeke, Michael C. Holmes, Scott Sproul, and Chester B. Whitley

Subjects

0301 basic medicine, Pharmacology, medicine.medical_specialty, Sulfatase, Albumin, Iduronate-2-sulfatase, Endogeny, Hunter syndrome, Enzyme replacement therapy, Biology, medicine.disease, 03 medical and health sciences, 030104 developmental biology, Endocrinology, In vivo, Internal medicine, Drug Discovery, Immunology, Genetics, medicine, Molecular Medicine, Mucopolysaccharidosis type II, Molecular Biology

Abstract

Hunter syndrome (Mucopolysaccharidosis Type II, MPS II) is a rare X-linked lysosomal disorder caused by lack of functional iduronate-2 sulfatase (IDS) enzyme and subsequent accumulation of glycosaminoglycans (GAG) in affected individuals. Manifestations include skeleton dysplasia, splenohepatomegaly, cardiopulmonary obstruction, and shortened life expectancy. In severe cases there is also neurologic impairment. Enzyme replacement therapy (ERT) is currently the only FDA-approved treatment to manage disease progression; however, ERT does not affect neurological aspects of the disease and requires that patients receive long and costly infusions of replacement factor on a frequent basis. We have developed a zinc-finger nuclease (ZFN) approach to insert the human IDS (hIDS) coding sequence into the albumin locus using AAV2/8 vectors. In this study IDS-deficient MPS II mice (n= 8-13 per group, age 7-8 weeks) were treated by intravenous infusion of a mixture of ZFN-encoding AAV vectors along with an AAV vector encoding the hIDS partial cDNA flanked by albumin sequence homology arms at three different vector doses. Wild-type littermates, untreated MPS II mice, and MPS II animals infused only with the hIDS donor vector (without ZFN-encoding vectors) were included as controls. Successful insertion of the hIDS coding sequence will result in hIDS expression regulated by the endogenous albumin promoter. Plasma and tissue IDS activities as well as urine and tissue GAG contents were monitored throughout the study to evaluate the effectiveness of the treatment. Sufficient animals were maintained for neurobehavioral testing at four-months post-injection to determine whether the treatment is neurologically beneficial. We found that IDS activities in the plasma of the treated groups were 10- to 100-fold higher than wild-type and stably expressed through the entire study duration in a dose-dependent fashion, while only very low levels of IDS activity were found in the animals infused with hIDS donor vector alone. At 4 weeks post-treatment IDS activities in peripheral tissues ranged from 1% to 200% wild-type in a dose-dependent fashion, while in the hIDS donor-only group enzyme activity was not detected in any tissue except liver (10% that of wild-type). We observed up to 2% of the wild-type IDS activity in the brains of animals administered the complete set of AAV vectors, while no IDS activity was observed in the brains of animals infused with the IDS donor vector alone. Urine GAGs were reduced in all of the ZFN + Donor treatment groups regardless of the vector dose. Tissue GAGs in the treatment groups were also decreased, but GAG content in the brain was not different from untreated MPS II litter mates at the initial analysis conducted four weeks post-treatment. No tissue GAG reduction was observed in animals infused with hIDS donor vector alone. Before conclusion of this study, animals from all six groups will be tested in the Barnes Maze as neurobehavioral assessment to determine the neurological effect of targeted hIDS expression in the liver. These results together with hIDS expression and GAG level data from final necropsy tissues will be presented. These results demonstrate that ZFN can be effectively used to mediate in vivo insertion of the hIDS coding sequence into the albumin locus with resultant stable and high-level hIDS enzyme expression and metabolic correction in MPS II.

Published

2016

5. 479. ZFN-Mediated In Vivo Genome Editing Results in Supraphysiological Levels of Lysosomal Enzymes Deficient in Hunter and Hurler Syndrome and Gaucher Disease

Author

Susan Tom, Thomas Wechsler, Leo Ou, Kanut Laoharawee, Chester B. Whitley, Scott Sproul, Philip D. Gregory, Scott McIvor, Michelle Rohde, Russel DeKelver, Kelly M. Podetz-Pedersen, and Michael C. Holmes

Subjects

Pharmacology, Transgene, Hunter syndrome, Enzyme replacement therapy, Biology, medicine.disease, Zinc finger nuclease, Genome editing, Drug Discovery, Immunology, Genetics, medicine, Cancer research, Molecular Medicine, Substrate reduction therapy, Hurler syndrome, Molecular Biology, Glucocerebrosidase

Abstract

Lysosomal storage diseases (LSDs) represent a group of inherited metabolic disorders associated with mutations in genes encoding lysosomal enzymes leading to systemic accumulation of toxic storage materials. Manifestations include organomegaly, skeletal dysplasias, cardiopulmonary obstruction, and severe neurologic impairment, often leading to death by age 10. Current LSD therapies include enzyme replacement therapy, substrate reduction therapy and hematopoietic stem cell transplant (HSCT). However, all of these therapies are expensive, incompletely effective, and HSCT is associated with significant risk of morbidity and mortality. Due to the unmet need genome editing strategies are proposed to permanently modify patient cells by genetically complementing the LSD defect. This is achieved by utilizing engineered zinc finger nucleases (ZFNs) to introduce a DNA cut at the target locus, mediating integration of a therapeutic LSD donor cDNA. To ensure long-term expression of the transgenes in vivo we target the albumin locus as a “safe harbor” in hepatocytes via co-delivery of the albumin ZFNs and LSD donors by adeno-associated virus (AAV). This system exploits the high transcriptional activity of the native albumin enhancer/promoter; uses stably modified hepatocytes to potentially allow long-term expression of the inserted transgene; and utilizes an endogenous promoter obviating this requirement in the AAV payload. We have previously exploited AAV-mediated in vivo targeting of the murine albumin “safe harbor” locus for the synthesis of therapeutic levels of FVIII and FIX to overcome the clotting defect in hemophilic mice. Using the same approach, we co-delivered mouse albumin ZFNs with donor constructs encoding either human iduronate-2-sulfatase (IDS) deficient in Hunter syndrome, α-L-iduronidase (IDUA) for Hurler syndrome, or Glucocerebrosidase (GBA) for Gaucher disease via AAV in WT mice. We show stable integration of the LSD donors at the albumin locus, resulting in liver-specific expression and secretion of these proteins into plasma. This led to a 4-fold (GBA), 10-fold (IDUA) or 100-fold (IDS) increase in enzymatic activity in the plasma, demonstrating that the secreted proteins are functional. Importantly, increased activity was also detected in secondary tissues (spleen) showing efficient uptake and activity in distal tissues. Moreover, preliminary data in MPSI and MPSII mice suggests these levels of IDS and IDUA expression may lead to correction of the enzyme deficiency. IDS, IDUA and GBA expression remained stable throughout the study (up to 2 months), while expression of FIX has been stable for >1 yr suggesting this process results in long-term protein expression. In summary, our data provide proof of concept for ZFN-mediated targeting of the albumin locus in hepatocytes as an in vivo protein replacement platform to express different proteins associated with lysosomal storage diseases.

Published

2015