Unraveling what makes a monoclonal antibody difficult-to-express: From intracellular accumulation to incomplete folding and degradation via ERAD.

Although most therapeutic monoclonal antibodies (mAbs) can routinely be produced in the multigram per litre range, some mAb candidates turn out to be difficult-to-express (DTE). In addition, the class of more complex biological formats is permanently increasing and mammalian expression systems like Chinese hamster ovary (CHO) cell lines can show low performance. Hence, there is an urgent need to identify any rate limiting processing step during cellular synthesis. Therefore, we assessed the intracellular location of the DTE antibody mAb2 by fluorescence and electron microscopy (EM) and revealed an accumulation of the antibody, which led to an aberrant morphology of the endoplasmic reticulum (ER). Analysis of underlying cellular mechanisms revealed that neither aggregation nor antibody assembly, but folding represented the reason for hampered secretion. We identified that the disulfide bridge formation within the antibody light chain (LC) was impaired due to less recognition by protein disulfide isomerase (PDI). As a consequence, the DTE molecule was degraded intracellularly by the ubiquitin proteasome system via ER-associated degradation (ERAD). This study revealed that with the continuous emergence of DTE therapeutic protein candidates, special attention needs to be drawn to optimization processes to ensure manufacturability.

DNA methylation in CHO cells.

Chinese hamster ovary (CHO) cells account for the production of the majority of biopharmaceutical molecules - however, the molecular basis for their versatile properties is not entirely understood yet and the underlying cellular processes need to be characterized in detail. One such process that is supposed to contribute significantly to CHO cell phenotype is methylation of DNA at cytosine residues. DNA methylation was shown to be involved in several central biological processes in humans and to contribute to diseases like cancer. Early studies of DNA methylation in CHO mostly focused on methylation of single recombinant genes and promoters and proved a correlation between DNA methylation status and recombinant gene expression or production stability. More recent publications utilized the CHO genomic and transcriptomic data available since 2011 and provided first insights into the CHO DNA methylation landscape and DNA methylation changes in response to effector molecules or culture conditions. Generally, further genome-wide studies of DNA methylation in CHO will be required to shed light on the relevance of this process regarding biopharmaceuticals production and might, e.g., address a potential link between CHO cell metabolism and DNA methylation or provide novel targets for rational cell line engineering.

Integrative analysis of DNA methylation and gene expression in butyrate-treated CHO cells.

The cellular mechanisms responsible for the versatile properties of CHO cells as the major production cell line for biopharmaceutical molecules are not entirely understood yet, although several 'omics' data facilitate the understanding of CHO cells and their reactions to environmental conditions. However, genome-wide studies of epigenetic processes such as DNA methylation are still limited. To prove the applicability and usefulness of integrating DNA methylation and gene expression data in a biotechnological context, we exemplarily analyzed the time course of cellular reactions upon butyrate addition in antibody-producing CHO cells by whole-genome bisulfite sequencing and CHO-specific cDNA microarrays. Gene expression and DNA methylation analyses showed that pathways known to be affected by butyrate, including cell cycle and apoptosis, as well as pathways potentially involved in butyrate-induced hyperproductivity such as central energy metabolism and protein biosynthesis were affected. Differentially methylated regions were furthermore found to contain binding-site motifs of specific transcription factors and were hypothesized to represent regulatory regions closely connected to the cellular response to butyrate. Generally, our experiment underlines the benefit of integrating DNA methylation and gene expression data, as it provided potential novel candidate genes for rational cell line development and allowed for new insights into the butyrate effect on CHO cells.

The DNA methylation landscape of Chinese hamster ovary (CHO) DP-12 cells.

Chinese hamster ovary (CHO) cells represent the most commonly used production cell line for therapeutic proteins. By recent genome and transcriptome sequencing a basis was created for future investigations of genotype-phenotype relationships and for improvement of CHO cell productivity and product quality. In this context information is missing about DNA cytosine methylation as a crucial epigenetic modification and an important element in mammalian genome regulation and development. Here, we present the first DNA methylation map of a CHO cell line in single-base resolution that was generated by whole genome bisulfite sequencing combined with gene expression analysis by CHO microarrays. We show CHO DP-12 cells to exhibit global hypomethylation compared to a majority of mammalian methylomes and hypermethylation of CpG-dense regions at gene promoters called CpG islands. We also observed partially methylated domains that cover 62% of the CHO DP-12 cell genome and contain functional clusters of genes. Gene expression analysis showed these clusters to be either highly or weakly expressed with regard to CHO-specific characteristics and hence proves DNA methylation in CHO cells to be an important link between genomics and transcriptomics.

Establishment of a CpG island microarray for analyses of genome-wide DNA methylation in Chinese hamster ovary cells.

Optimizing productivity and growth rates of recombinant Chinese hamster ovary (CHO) cells requires insight into the regulation of cellular processes. In this regard, the elucidation of the epigenetic process of DNA methylation, known to influence transcription by a differential occurrence in CpG islands in promoter regions, is increasingly gaining importance. However, DNA methylation has not yet been investigated on a genomic scale in CHO cells and suitable tools have not existed until now. Based on the genomic and transcriptomic CHO data currently available, we developed a customized oligonucleotide microarray covering 19598 CpG islands (89 % of total bioinformatically identified CpG islands) in the CHO genome. We applied our CHO-specific CpG island microarray to investigate the effect of butyrate treatment on differential DNA methylation in CHO cultures in a time-dependent approach. Supplementation of butyrate is known to enhance cell specific productivities in CHO cells and leads to alterations of epigenetic silencing events. Gene ontology clusters regarding, e.g., chromatin modification or DNA repair, were significantly overrepresented 24 h after butyrate addition. Functional classifications furthermore indicated that several major signaling systems such as the Wnt/ß-catenin pathway were affected by butyrate treatment. Our novel CHO-specific CpG island microarray will provide valuable information in future studies of cellular processes associated with productivity and product characteristics.