Here, we describe a method that offers a unique way to engineer plasmids with precision but without digestion using restriction enzymes for the insertion of DNA. The method allows the insertion of PCR fragments in between any two nucleotides within a target plasmid. The only requirement is that the amplified fragments must be embedded between DNA sequences homologous to the site in which the integration is planned. This method is an adaptation of the QuikChange Site-Directed Mutagenesis protocol. It is simpler than the existing cloning strategies and is suitable for multiparallel constructions of new plasmids. We have demonstrated its utility by constructing plasmids in which we have successfully integrated PCR fragments up to 1117 bp.
Cell line generation for production of biopharmaceuticals in mammalian cells usually involves intensive screening of clones to identify the rare high producers. In order to facilitate efficient and selective fluorescence activated cell sorting (FACS) based enrichment and cloning of antibody producing CHO cells, we developed a special vector setup by inserting a leaky translation termination signal between the heavy chain of an IgG antibody and an IgG transmembrane domain. Partial read-through during translation of the antibody heavy chain leads to display of a subset of the produced antibody on the surface of the expressing cell. We could show that the level of surface expression correlates well with the productivity. By applying FACS, high producing cells can be selectively enriched and cloned. Two sequential FACS enrichment cycles were performed which led to more than eightfold increased productivities of transfected and selected cell populations without cloning. The combination of selective FACS enrichment and FACS cloning with the new vector setup led to a sevenfold higher average productivity of the resulting clones as compared to a reference vector. Productivity and production stability assessment of clones generated with the new vector showed no negative impact of the co-expression of transmembrane antibody. Clone productivities of 4 g/L in a generic shake flask fed-batch model were achieved. Thus, this new vector setup facilitates fast and selective isolation of high producing production cell lines and allows significant reduction of clone screening efforts during cell line development for production cell lines. Additionally, the high productivity of FACS-enriched but non-clonal cell populations supports rapid, high yield, and cost efficient material production in early project phases. Biotechnol. Bioeng. 2016;113: 2386-2393. © 2016 Wiley Periodicals, Inc.
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