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8 results on '"λ Integrase"'

1. A versatile genomic transgenesis platform with enhanced λ integrase for human Expi293F cells

Author

Asim Azhar Siddiqui, Sabrina Peter, Eve Zi Xian Ngoh, Cheng-I. Wang, Shirelle Ng, John A. Dangerfield, Walter H. Gunzburg, Peter Dröge, and Harshyaa Makhija

Subjects
human cell line engineering, λ integrase, Expi293F cells, biotherapeutics, site-specific transgenesis, microencapsulation, Biotechnology, TP248.13-248.65
Abstract

Reliable cell-based platforms to test and/or produce biologics in a sustainable manner are important for the biotech industry. Utilizing enhanced λ integrase, a sequence-specific DNA recombinase, we developed a novel transgenesis platform involving a fully characterized single genomic locus as an artificial landing pad for transgene insertion in human Expi293F cells. Importantly, transgene instability and variation in expression were not observed in the absence of selection pressure, thus enabling reliable long-term biotherapeutics testing or production. The artificial landing pad for λ integrase can be targeted with multi-transgene constructs and offers future modularity involving additional genome manipulation tools to generate sequential or nearly seamless insertions. We demonstrated broad utility with expression constructs for anti PD-1 monoclonal antibodies and showed that the orientation of heavy and light chain transcription units profoundly affected antibody expression levels. In addition, we demonstrated encapsulation of our PD-1 platform cells into bio-compatible mini-bioreactors and the continued secretion of antibodies, thus providing a basis for future cell-based applications for more effective and affordable therapies.

Published
2023
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2. A versatile genomic transgenesis platform with enhanced λ integrase for human Expi293F cells

Author

Siddiqui, Asim Azhar, Peter, Sabrina, Ngoh, Eve Zi Xian, Wang, Cheng-I, Ng, Shirelle, Dangerfield, John A., Gunzburg, Walter H., Dröge, Peter, Makhija, Harshyaa, School of Biological Sciences, and Singapore Immunology Network, A*STAR

Subjects
Human Cell Line Engineering, Biotherapeutics, Site-Specific Transgenesis, Science, λ Integrase, Expi293F Cells, Microencapsulation
Abstract

Reliable cell-based platforms to test and/or produce biologics in a sustainable manner are important for the biotech industry. Utilizing enhanced λ integrase, a sequence-specific DNA recombinase, we developed a novel transgenesis platform involving a fully characterized single genomic locus as an artificial landing pad for transgene insertion in human Expi293F cells. Importantly, transgene instability and variation in expression were not observed in the absence of selection pressure, thus enabling reliable long-term biotherapeutics testing or production. The artificial landing pad for λ integrase can be targeted with multi-transgene constructs and offers future modularity involving additional genome manipulation tools to generate sequential or nearly seamless insertions. We demonstrated broad utility with expression constructs for anti PD-1 monoclonal antibodies and showed that the orientation of heavy and light chain transcription units profoundly affected antibody expression levels. In addition, we demonstrated encapsulation of our PD-1 platform cells into bio-compatible mini-bioreactors and the continued secretion of antibodies, thus providing a basis for future cell-based 32 applications for more effective and affordable therapies. Agency for Science, Technology and Research (A*STAR) National Research Foundation (NRF) Published version This work was supported through a grant from the National Research Foundation-Competitive Research Programme, Singapore to P.D. (NRF-CRP21-2018-0002), and the Core Fund from the Singapore Immunology Network, Agency for Science, Technology and Research, Singapore to C-I.W.

Published
2023

3. A versatile genomic transgenesis platform with enhanced λ integrase for human Expi293F cells.

Author

Siddiqui AA, Peter S, Ngoh EZX, Wang CI, Ng S, Dangerfield JA, Gunzburg WH, Dröge P, and Makhija H

Abstract

Reliable cell-based platforms to test and/or produce biologics in a sustainable manner are important for the biotech industry. Utilizing enhanced λ integrase, a sequence-specific DNA recombinase, we developed a novel transgenesis platform involving a fully characterized single genomic locus as an artificial landing pad for transgene insertion in human Expi293F cells. Importantly, transgene instability and variation in expression were not observed in the absence of selection pressure, thus enabling reliable long-term biotherapeutics testing or production. The artificial landing pad for λ integrase can be targeted with multi-transgene constructs and offers future modularity involving additional genome manipulation tools to generate sequential or nearly seamless insertions. We demonstrated broad utility with expression constructs for anti PD-1 monoclonal antibodies and showed that the orientation of heavy and light chain transcription units profoundly affected antibody expression levels. In addition, we demonstrated encapsulation of our PD-1 platform cells into bio-compatible mini-bioreactors and the continued secretion of antibodies, thus providing a basis for future cell-based applications for more effective and affordable therapies., Competing Interests: Authors SN, JD, and WG were employed by Austrianova Singapore Pte. Ltd.; Authors HM and PD are the co-founders and shareholders of LambdaGen Pte. Ltd. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2023 Siddiqui, Peter, Ngoh, Wang, Ng, Dangerfield, Gunzburg, Dröge and Makhija.)

Published
2023
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4. Protein folding coupled to DNA binding in the catalytic domain of bacteriophage λ integrase detected by mass spectrometry.

Author

Kamadurai, Hari B., Subramaniam, Srisunder, Jones, R. Benjamin, Green-Church, Kari B., and Foster, Mark P.

Abstract

Bacteriophage λ integrase (λ-Int) is the prototypical member of a large family of enzymes that catalyze site-specific DNA recombination via single-strand cleavage and the formation of a Holliday junction intermediate. Crystallographic and biochemical evidence indicate that substantial conformational change (i.e., folding) in the catalytic domain of the protein is required for substrate recognition and catalysis. We have examined the solution conformation of the catalytic domain (C170) in the absence and presence of a cognate 'half-site' DNA oligonucleotide by electrospray ionization mass spectrometry, and circular dichroism and fluorescence spectroscopy. The distribution of ions in the positive ion electrospray mass spectrum of the free protein reveals the presence of three distinct species in solution, one corresponding to the folded protein, one to the unfolded protein, and one to a dimer. In the presence of DNA, ions are observed only for the protein-DNA complex and the folded form of the free protein. We therefore conclude that DNA binding stabilizes the global fold of the protein in a manner that is consistent with folding-coupled target recognition as a mechanism to control site-specific recombination. Furthermore, we find that inspection of the charge state distribution of ions in electrospray mass spectra provides a quick and effective means to identify conformational heterogeneity of proteins in solution and to investigate dynamic protein-nucleic acid interactions. [ABSTRACT FROM AUTHOR]

Published
2003
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