Markus Imhof

Development of stable cell lines for production or regulated expression using matrix attachment regions

One of the major hurdles of isolating stable, inducible or constitutive high-level producer cell lines is the time-consuming selection procedure. Given the variation in the expression levels of the same construct in individual clones, hundreds of clones must be isolated and tested to identify one or more with the desired characteristics. Various boundary elements (BEs), matrix attachment regions, and locus control regions (LCRs) were screened for their ability to augment the expression of heterologous genes in Chinese hamster ovary (CHO) cells. Of the chromatin elements assayed, the chicken lysozyme matrix-attachment region (MAR) was the only element to significantly increase stable reporter expression. We found that the use of the MAR increases the proportion of high-producing clones, thus reducing the number of clones that need to be screened. These benefits are observed both for constructs with MARs flanking the transgene expression cassette, as well as when constructs are co-transfected with the MAR on a separate plasmid. Moreover, the MAR was co-transfected with a multicomponent regulatable beta-galactosidase expression system in C2C12 cells and several clones exhibiting regulated expression were identified. Hence, MARs are useful in the development of stable cell lines for production or regulated expression.

A regulatory network for the efficient control of transgene expression.

Expression of heterologous genes in mammalian cells or organisms for therapeutic or experimental purposes often requires tight control of transgene expression. Specifically, the following criteria should be met: no background gene activity in the off‐state, high gene expression in the on‐state, regulated expression over an extended period, and multiple switching between on‐ and off‐states.

Reversal of the silencing of tetracycline-controlled genes requires the coordinate action of distinctly acting transcription factors

Regulation of genes transferred to eukaryotic organisms is often limited by the lack of consistent expression levels in all transduced cells, which may result in part from epigenetic gene silencing effects. This reduces the efficacy of ligand‐controlled gene switches designed for somatic gene transfers such as gene therapy.

Comparative study and identification of potent eukaryotic transcriptional repressors in gene switch systems.

In mammalian cells, proper gene regulation is achieved by the complex interplay of transcription factors that activate or repress gene expression by binding to the regulatory regions of target promoters. While transcriptional activators have been extensively characterised and classified into functional groups, relatively little is known about the comparative strength and cell type-specificity of transcriptional repressors. Here, we have compared the ability of a series of eukaryotic repression domains to silence basal and activated transcription. A series of the most potent repression domains was further tested in the context of a gene therapy gene-switch system in various cell types. The results indicate that the analysed repression domains exert varying silencing activities in different promoter contexts. Furthermore, their potential for gene silencing varies also depending on the cellular context. When multimerised within one chimeric repressor protein, particular combinations of repressor domains were found to display synergistic repressing effects and efficient repression in a panel of cell lines. This approach thus allowed the identification of transcriptional repressors that are both potent and versatile in terms of cellular specificity as a basis for gene switch systems.

An efficient detection agent for the high throughput screening of recombinant manufacturing cell lines.

To ensure the selection of high producing recombinant cell lines, a number of screening processes were developed in the presence of detection agents. Here, CHO cell lines secreting recombinant antibodies were detected in semi-solid medium containing detection agents. The aim was to compare two protein A-derived detection agents to two commercial fluorescent antibodies directed against the Fc part of the antibody of interest: the protein A derived Z domain fused to the red fluorescent protein and protein A labelled with a fluorescent Dylight™ 488 dye. All of these agents were compatible with cell recovery and colony formation, and specifically detected colonies secreting recombinant antibodies. Optimisation of the concentration of the fluorescent protein A allowed the identification of a higher number of good producers. Thus these data demonstrate that fluorescently labelled protein A-derivatives can be used for the selection of high producer cells.