Benzinga | Nov 9, 2021 11:45AM EST

Applied DNA Sciences Highlights Publication Shows Utility Of Co.'s LinearDNA In Non-Viral CAR T Manufacturing Systems

- Preclinical Study Details Application of LinearDNA Suitable for the Cost-Effective Production of CAR T Cells -

- Results Demonstrate that CAR19 T-cells Manufactured with LinearDNA Have Similar Efficacy to CAR19 T-cells Manufactured with Plasmid DNA -

STONY BROOK, N.Y.--(BUSINESS WIRE)-- Applied DNA Sciences, Inc. (NASDAQ:APDN) (Applied DNA or the "Company"), a leader in Polymerase Chain Reaction (PCR)-based DNA manufacturing and nucleic acid-based technologies, announced the publication of a study in Molecular Therapy: Methods and Clinical Development on a methodology for the manufacture of novel types of CAR constructs that employ the Company's LinearDNA(tm) as part of a manufacturing process for the efficient generation of CD19-specific CAR T-cells (CAR19 T-cells) based on co-electroporation of a LinearDNA transposon and mRNA encoding of piggyBac transposase. PCR-produced LinearDNA is manufactured by LineaRx, the Company's majority-owned subsidiary, to serve as a pure, fast, and flexible alternative to plasmid DNA (pDNA) for biotherapeutic applications.

The study, titled "Enzymatically produced piggyBac transposon vectors for efficient non-viral manufacturing of CD19-specific CAR T cells", details the utility of LinearDNA in the cost-effective production of preclinical CAR T cells. Its authors, members of the Institute of Hematology and Blood Transfusion (?HKT) in Prague, Czechia, and the Faculty of Natural Sciences at Charles University, also in Prague, propose that the combination of LinearDNA and a transposon/transposase system offers therapy developers an effective research tool for making experimental CAR T cells rapidly and efficiently without the need for complicated virus production or the use of pDNA.

Pavel Ot?hal, contributing author and Head of the Gene Immunotherapy Research Department at ?HKT, stated, "Our study compares the manufacture of CAR19 T-cells via PCR-made transposon DNA (LinearDNA) with mRNA encoding of the transposase against a conventional plasmid approach. We found CAR T efficacy of the LinearDNA system versus the plasmid system to be identical. Further, we found no mutations in the coding sequence of LinearDNA and with >99% purity that obliviated the need for purification typical of a plasmid approach. As an institution dedicated to diagnosing and treating serious blood diseases and with the ability to pursue investigational medicines from development to manufacture and clinical trial for patients who have exhausted all approved treatment options, having a cost-effective and rapid production chain is integral to ?HKT's mission. We find LinearDNA to be an excellent platform for CAR T-cell therapy development."

Dr. James A. Hayward, president and CEO of Applied DNA, said, "The clinical successes of CAR T-cell therapy against blood cancers have been impressive, though limited by the complex production of viral vectors that are currently needed for T-cell genetic transformation and the use of pDNA. These manufacturing complexities have likewise hindered research on CAR T-cell therapies. As described in the publication, the use of LinearDNA, coupled with non-viral transfection systems, we believe, overcomes many of the existing manufacturing complexities associated with pDNA and viral vectors, thereby offering therapy developers a rapid and cost-effective tool for manufacturing preclinical CAR T cells. The authors' findings as it relates to LinearDNA coincide with the industry's growing interest in alternatives to pDNA for CAR T-cell therapies with approximately 50% of recent CRO orders coming from CAR T cell developers."

The detailed study write-up can be found at: Molecular Therapy: Methods and Clinical Development, the leading journal for research in the areas of gene transfer, vector development and design, stem cell manipulation, development of gene-, peptide-, protein-, oligonucleotide-, and cell-based therapeutics to correct genetic and acquired diseases, vaccine development, preclinical target validation, safety/efficacy studies, and clinical trials.