Characterization and biodistribution of under-employed gene therapy vector AAV7

Characterization and biodistribution of under-employed gene therapy vector AAV7

AAV7 is a clade D adeno-associated virus (AAV) whose potential as a gene therapy vector has not been fully evaluated. We show here that high-titer AAV7 vectors can be produced in HEK293 cells and used to transduce cultured cells in an AAV receptor (AAVR)-dependent manner. In contrast with AAV9, AAV7...

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Veröffentlicht in:Journal of virology 2023-11, Vol.97 (11), p.e0116323-e0116323
Hauptverfasser: Yost, Samantha A., Firlar, Emre, Glenn, Justin D., Carroll, Hayley B., Foltz, Steven, Giles, April R., Egley, Jenny M., Firnberg, Elad, Cho, Sungyeon, Nguyen, Trang, Henry, William M., Janczura, Karolina J., Bruder, Joseph, Liu, Ye, Danos, Olivier, Karumuthil-Melethil, Subha, Pannem, Sanjana, Yost, Valerie, Engelson, Yelena, Kaelber, Jason T., Dimant, Hemi, Smith, Jared B., Mercer, Andrew C.
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Gene Delivery
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container_end_page e0116323
container_issue 11
container_start_page e0116323
container_title Journal of virology
container_volume 97
creator Yost, Samantha A.
Firlar, Emre
Glenn, Justin D.
Carroll, Hayley B.
Foltz, Steven
Giles, April R.
Egley, Jenny M.
Firnberg, Elad
Cho, Sungyeon
Nguyen, Trang
Henry, William M.
Janczura, Karolina J.
Bruder, Joseph
Liu, Ye
Danos, Olivier
Karumuthil-Melethil, Subha
Pannem, Sanjana
Yost, Valerie
Engelson, Yelena
Kaelber, Jason T.
Dimant, Hemi
Smith, Jared B.
Mercer, Andrew C.
description AAV7 is a clade D adeno-associated virus (AAV) whose potential as a gene therapy vector has not been fully evaluated. We show here that high-titer AAV7 vectors can be produced in HEK293 cells and used to transduce cultured cells in an AAV receptor (AAVR)-dependent manner. In contrast with AAV9, AAV7 did not significantly interact with glycans when assayed on a panel of three hundred biologically relevant species. The structure of the AAV7 capsid was obtained by single particle cryo-electron microscopy at 2.7 Å, showing the expected AAV scaffold as well as unique features in variable surface loops. The biodistribution profiles of AAV7 and AAV9 vectors were compared in mice following intravenous administration and quantification of vector genomes and mRNA in tissues, as well as cryofluorescence tomography (CFT) and immunofluorescence (IF). AAV7 displayed a strong cardiac tropism and did not efficiently cross the blood-brain barrier. Surprisingly, strong transgene expression was observed throughout the head as shown by CFT, including regions of the cranial sinuses, teeth, and mandible for both AAV7 and AAV9, an attribute that has not been previously evaluated via traditional biodistribution methods. The use of adeno-associated viruses (AAVs) as gene delivery vectors has vast potential for the treatment of many severe human diseases. Over one hundred naturally existing AAV capsid variants have been described and classified into phylogenetic clades based on their sequences. AAV8, AAV9, AAVrh.10, and other intensively studied capsids have been propelled into pre-clinical and clinical use, and more recently, marketed products; however, less-studied capsids may also have desirable properties (e.g., potency differences, tissue tropism, reduced immunogenicity, etc.) that have yet to be thoroughly described. These data will help build a broader structure-function knowledge base in the field, present capsid engineering opportunities, and enable the use of novel capsids with unique properties.
doi_str_mv 10.1128/jvi.01163-23
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We show here that high-titer AAV7 vectors can be produced in HEK293 cells and used to transduce cultured cells in an AAV receptor (AAVR)-dependent manner. In contrast with AAV9, AAV7 did not significantly interact with glycans when assayed on a panel of three hundred biologically relevant species. The structure of the AAV7 capsid was obtained by single particle cryo-electron microscopy at 2.7 Å, showing the expected AAV scaffold as well as unique features in variable surface loops. The biodistribution profiles of AAV7 and AAV9 vectors were compared in mice following intravenous administration and quantification of vector genomes and mRNA in tissues, as well as cryofluorescence tomography (CFT) and immunofluorescence (IF). AAV7 displayed a strong cardiac tropism and did not efficiently cross the blood-brain barrier. Surprisingly, strong transgene expression was observed throughout the head as shown by CFT, including regions of the cranial sinuses, teeth, and mandible for both AAV7 and AAV9, an attribute that has not been previously evaluated via traditional biodistribution methods. The use of adeno-associated viruses (AAVs) as gene delivery vectors has vast potential for the treatment of many severe human diseases. Over one hundred naturally existing AAV capsid variants have been described and classified into phylogenetic clades based on their sequences. AAV8, AAV9, AAVrh.10, and other intensively studied capsids have been propelled into pre-clinical and clinical use, and more recently, marketed products; however, less-studied capsids may also have desirable properties (e.g., potency differences, tissue tropism, reduced immunogenicity, etc.) that have yet to be thoroughly described. 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Surprisingly, strong transgene expression was observed throughout the head as shown by CFT, including regions of the cranial sinuses, teeth, and mandible for both AAV7 and AAV9, an attribute that has not been previously evaluated via traditional biodistribution methods. The use of adeno-associated viruses (AAVs) as gene delivery vectors has vast potential for the treatment of many severe human diseases. Over one hundred naturally existing AAV capsid variants have been described and classified into phylogenetic clades based on their sequences. AAV8, AAV9, AAVrh.10, and other intensively studied capsids have been propelled into pre-clinical and clinical use, and more recently, marketed products; however, less-studied capsids may also have desirable properties (e.g., potency differences, tissue tropism, reduced immunogenicity, etc.) that have yet to be thoroughly described. 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subjects Gene Delivery
title Characterization and biodistribution of under-employed gene therapy vector AAV7
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