Your search keyword '"Fung EK"' showing total 3 results

1. Bidirectional regulation of motor circuits using magnetogenetic gene therapy.

Author

Unda SR, Pomeranz LE, Marongiu R, Yu X, Kelly L, Hassanzadeh G, Molina H, Vaisey G, Wang P, Dyke JP, Fung EK, Grosenick L, Zirkel R, Antoniazzi AM, Norman S, Liston CM, Schaffer C, Nishimura N, Stanley SA, Friedman JM, and Kaplitt MG

Subjects

Animals, Mice, Parkinson Disease therapy, Parkinson Disease genetics, Parkinson Disease metabolism, Genetic Vectors genetics, Humans, Subthalamic Nucleus metabolism, Magnetic Fields, Globus Pallidus metabolism, Receptor, Adenosine A2A metabolism, Receptor, Adenosine A2A genetics, Neurons metabolism, Corpus Striatum metabolism, TRPV Cation Channels, Genetic Therapy methods, Dependovirus genetics

Abstract

Here, we report a magnetogenetic system, based on a single anti-ferritin nanobody-TRPV1 receptor fusion protein, which regulated neuronal activity when exposed to magnetic fields. Adeno-associated virus (AAV)-mediated delivery of a floxed nanobody-TRPV1 into the striatum of adenosine-2a receptor-Cre drivers resulted in motor freezing when placed in a magnetic resonance imaging machine or adjacent to a transcranial magnetic stimulation device. Functional imaging and fiber photometry confirmed activation in response to magnetic fields. Expression of the same construct in the striatum of wild-type mice along with a second injection of an AAVretro expressing Cre into the globus pallidus led to similar circuit specificity and motor responses. Last, a mutation was generated to gate chloride and inhibit neuronal activity. Expression of this variant in the subthalamic nucleus in PitX2-Cre parkinsonian mice resulted in reduced c-fos expression and motor rotational behavior. These data demonstrate that magnetogenetic constructs can bidirectionally regulate activity of specific neuronal circuits noninvasively in vivo using clinically available devices.

Published

2024

2. Positron Emission Tomography Quantitative Assessment of Off-Target Whole-Body Biodistribution of I-124-Labeled Adeno-Associated Virus Capsids Administered to Cerebral Spinal Fluid.

Author

Rosenberg JB, Fung EK, Dyke JP, De BP, Lou H, Kelly JM, Reejhsinghani L, Ricart Arbona RJ, Sondhi D, Kaminsky SM, Cartier N, Hinderer C, Hordeaux J, Wilson JM, Ballon DJ, and Crystal RG

Subjects

Animals, Iodine Radioisotopes, Capsid, Tissue Distribution, Transduction, Genetic, Genetic Therapy methods, Positron-Emission Tomography, Genetic Vectors genetics, Gene Transfer Techniques, Dependovirus genetics, Nervous System Diseases

Abstract

Based on studies in experimental animals demonstrating that administration of adeno-associated virus (AAV) vectors to the cerebrospinal fluid (CSF) is an effective route to transfer genes to the nervous system, there are increasing number of clinical trials using the CSF route to treat nervous system disorders. With the knowledge that the CSF turns over four to five times daily, and evidence in experimental animals that at least some of CSF administered AAV vectors are distributed to systemic organs, we asked: with AAV administration to the CSF, what fraction of the total dose remains in the nervous system and what fraction goes off target and is delivered systemically? To quantify the biodistribution of AAV capsids immediately after administration, we covalently labeled AAV capsids with iodine 124 (I-124), a cyclotron generated positron emitter, enabling quantitative positron emission tomography scanning of capsid distribution for up to 96 h after AAV vector administration. We assessed the biodistribution to nonhuman primates of I-124-labeled capsids from different AAV clades, including 9 (clade F), rh.10 (E), PHP.eB (F), hu68 (F), and rh91(A). The analysis demonstrated that 60-90% of AAV vectors administered to the CSF through either the intracisternal or intrathecal (lumbar) routes distributed systemically to major organs. These observations have potentially significant clinical implications regarding accuracy of AAV vector dosing to the nervous system, evoking systemic immunity at levels similar to that with systemic administration, and potential toxicity of genes designed to treat nervous system disorders being expressed in non-nervous system organs. Based on these data, individuals in clinical trials using AAV vectors administered to the CSF should be monitored for systemic as well as nervous system adverse events and CNS dosing considerations should account for a significant AAV systemic distribution.

Published

2023

3. Quantitative Whole-Body Imaging of I-124-Labeled Adeno-Associated Viral Vector Biodistribution in Nonhuman Primates.

Author

Ballon DJ, Rosenberg JB, Fung EK, Nikolopoulou A, Kothari P, De BP, He B, Chen A, Heier LA, Sondhi D, Kaminsky SM, Mozley PD, Babich JW, and Crystal RG

Subjects

Animals, Brain metabolism, Brain pathology, Brain virology, Dependovirus chemistry, Genetic Vectors genetics, Humans, Iodine Radioisotopes chemistry, Primates, Tissue Distribution drug effects, Brain diagnostic imaging, Dependovirus genetics, Iodine Radioisotopes pharmacology, Whole Body Imaging methods

Abstract

A method is presented for quantitative analysis of the biodistribution of adeno-associated virus (AAV) gene transfer vectors following in vivo administration. We used iodine-124 (I-124) radiolabeling of the AAV capsid and positron emission tomography combined with compartmental modeling to quantify whole-body and organ-specific biodistribution of AAV capsids from 1 to 72 h following administration. Using intravenous (IV) and intracisternal (IC) routes of administration of AAVrh.10 and AAV9 vectors to nonhuman primates in the absence or presence of anticapsid immunity, we have identified novel insights into initial capsid biodistribution and organ-specific capsid half-life. Neither I-124-labeled AAVrh.10 nor AAV9 administered intravenously was detected at significant levels in the brain relative to the administered vector dose. Approximately 50% of the intravenously administered labeled capsids were dispersed throughout the body, independent of the liver, heart, and spleen. When administered by the IC route, the labeled capsid had a half-life of ∼10 h in the cerebral spinal fluid (CSF), suggesting that by this route, the CSF serves as a source with slow diffusion into the brain. For both IV and IC administration, there was significant influence of pre-existing anticapsid immunity on I-124-capsid biodistribution. The methodology facilitates quantitative in vivo viral vector dosimetry, which can serve as a technique for evaluation of both on- and off-target organ biodistribution, and potentially accelerate gene therapy development through rapid prototyping of novel vector designs.

Published

2020