Molecular Therapy: Methods & Clinical Development (Jun 2024)

A robust and flexible baculovirus-insect cell system for AAV vector production with improved yield, capsid ratios and potency

  • Yoko Marwidi,
  • Hoang-Oanh B. Nguyen,
  • David Santos,
  • Tenzin Wangzor,
  • Sumita Bhardwaj,
  • Gabriel Ernie,
  • Gregg Prawdzik,
  • Garrett Lew,
  • David Shivak,
  • Michael Trias,
  • Jada Padilla,
  • Hung Tran,
  • Kathleen Meyer,
  • Richard Surosky,
  • Alex Michael Ward

Journal volume & issue
Vol. 32, no. 2
p. 101228

Abstract

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Manufacturing of adeno-associated viruses (AAV) for gene and cell therapy applications has increased significantly and spurred development of improved mammalian and insect cell-based production systems. We developed a baculovirus-based insect cell production system—the SGMO Helper—with a novel gene architecture and greater flexibility to modulate the expression level and content of individual Rep and Cap proteins. In addition, we incorporated modifications to the AAV6 capsid sequence that improves yield, capsid integrity, and potency. Production of recombinant AAV 6 (rAAV6) using the SGMO Helper had improved yields compared to the Bac-RepCap helper from the Kotin lab. SGMO Helper-derived rAAV6 is resistant to a previously described proteolytic cleavage unique to baculovirus-insect cell production systems and has improved capsid ratios and potency, in vitro and in vivo, compared with rAAV6 produced using Bac-RepCap. Next-generation sequencing sequence analysis demonstrated that the SGMO Helper is stable over six serial passages and rAAV6 capsids contain comparable amounts of non-vector genome DNA as rAAV6 produced using Bac-RepCap. AAV production using the SGMO Helper is scalable using bioreactors and has improved yield, capsid ratio, and in vitro potency. Our studies demonstrate that the SGMO Helper is an improved platform for AAV manufacturing to enable delivery of cutting-edge gene and cell therapies.

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