Project description:CHO cells are major hosts for the industrial production of therapeutic proteins and their production stability is of considerable economic significance. It is widely known that CHO cells can rapidly acquire genetic alterations, which affects their genetic homogeneity over time. However, the role of non-genetic mechanisms, including epigenetic mechanisms such as DNA methylation, remains poorly understood. We have now used whole-genome bisulfite sequencing to establish single-base methylation maps of eight independent CHO cell lines. Our results identify CpG islands and low-methylated regions as conserved elements with dynamic DNA methylation. Interestingly, methylation patterns were found to cluster clearly along the three main branches of CHO evolution, with no directional changes over short culture periods. Furthermore, multi-ome single-cell sequencing of 9,833 nuclei from three independent cultures revealed dynamic subpopulation structures characterized by robust expression differences in pathways related to protein production. Our findings thus provide novel insights into the epigenetic heterogeneity of CHO cells and support the development of epigenetic biomarkers that trace the emergence of subpopulations in CHO cultures.

Project description:CHO cells are major hosts for the industrial production of therapeutic proteins and their production stability is of considerable economic significance. It is widely known that CHO cells can rapidly acquire genetic alterations, which affects their genetic homogeneity over time. However, the role of non-genetic mechanisms, including epigenetic mechanisms such as DNA methylation, remains poorly understood. We have now used whole-genome bisulfite sequencing to establish single-base methylation maps of eight independent CHO cell lines. Our results identify CpG islands and low-methylated regions as conserved elements with dynamic DNA methylation. Interestingly, methylation patterns were found to cluster clearly along the three main branches of CHO evolution, with no directional changes over short culture periods. Furthermore, multi-ome single-cell sequencing of 9,833 nuclei from three independent cultures revealed dynamic subpopulation structures characterized by robust expression differences in pathways related to protein production. Our findings thus provide novel insights into the epigenetic heterogeneity of CHO cells and support the development of epigenetic biomarkers that trace the emergence of subpopulations in CHO cultures.

Project description:The development of next-generation sequencing technologies has opened new opportunities to better characterize complex eukaryotic cells. Chinese hamster ovary (CHO) cells play a primary role in therapeutic protein production, with currently five of the top ten blockbuster selling drugs produced in CHO. However, engineering superior CHO cells with improved production features has had limited results to date and cell lines are still developed through generation and screening of large strain pools. Here, we applied RNA sequencing to contrast a high and a low monoclonal antibody producing cell line. Rigorous experimental design achieved high reproducibility between biological replicates, remarkably reducing variation to less than 10%. More than 14,000 gene-transcripts were identified and surprisingly 58% were classified as differentially expressed, including 2,900 with a fold change higher than 1.5. The largest differences were found for gene-transcripts belonging to regulation of apoptosis, cell death and protein intracellular transport GO term classifications, which were found to be significantly enriched in the high producing cell line. RNA sequencing was also performed to lower producing subclones, where down-regulation of genes encoding secreted glycoproteins was found to be the most significant change. The large number of significant differences even between subclones suggests a substantial genetic fluidity in CHO lines and challenges the notion of identifying and manipulating a few key genes to generate high production CHO cell lines.

Project description:In biopharmaceutical production, Chinese hamster ovary (CHO) cells derived from Cricetulus griseus remain the most commonly used host cell for recombinant protein production, especially antibodies. Over the last decade in-depth multi-omics characterization of these CHO cells provided data for extensive cell line engineering and corresponding increases in productivity. exosomes, extracellular vesicles containing proteins and nucleic acids, are barely researched at all in CHO cells. Exosomes have been proven to be an ubiquitous mediator of intercellular communication and are proposed as new biopharmaceutical format for drug delivery, indicator reflecting host cell condition and anti-apoptotic factor in spent media. Here we sequenced non-coding RNA of Exosomes (EXO) and whole cell lysate (WCL) isolated from CHO-K1 Cell Cultures at different growth phases (logarithmic/exponential phase (log/exp), stationary phase (stat), as well as death phase at 80 % viability (80 % ) and 60 % viability (60 %)) via Lexogen Small RNA-Seq Library Prep Kit for Illumina on the Illumina MiSeq platform in PE mode 2 x 36nt.

Project description:Gene expression is a key determinant of phenotypes that made Chinese Hamster Ovary (CHO) cells, with their human-like glycosylation profile and high protein titers, one of the most widely used cells for the production of therapeutic proteins and biopharmaceuticals. Engineering CHO gene expression thus holds a key to improve drug quality and cost effective production. However, the success of engineering gene expression or ectopic activation of silent genes to optimize desired pathways requires accurate annotation of the underlying regulatory elements and the transcription start site (TSS). Unfortunately, to date, most TSSs of CHO-expressed genes and the ~50% of hamster genes that are silent in CHO were computationally predicted and are frequently inaccurate. To oust this hurdle, we report revised TSSs annotations for 15,308 Chinese Hamster genes and 4,145 non-coding RNAs based on experimental data from CHO K1 cells and 10 hamster tissues. In the example of the glycosyltransferase gene Mgat3, we further demonstrate how accurate annotations readily facilitate activating silent genes by CRISPRa. Together, we envision that our annotation and data from the Chinese Hamster will provide a rich resource for the CHO community, improve genome engineering efforts and additionally aid comparative and evolutionary studies.

Project description:MicroRNAs are small non-coding RNAs that play a critical role in post-transcriptional control of gene expression. Recent publications of genomic sequencing data from CHO cells provide new tools for the discovery of novel miRNAs in this important production system. The current release of the miRNA registry miRBase contains 307 mature miRNAs and 200 precursor sequences. We searched for evolutionary conserved miRNAs in recently published genomic data, derived from hamster and CHO cells, to further extend the list of known miRNAs. With our approach we could identify several dozens novel miRNAs and verify their expression with multiple next-generation sequencing experiments. In addition, a great amount of unexpressed miRNAs could be found, awaiting further confirmation by testing for their transcription in different Chinese hamster tissues. Two batch processes with 6 samples each

Project description:CHO cells have primarily been studied in bulk, assuming that these bulk samples are identical because of genetic clonality across the sample. In this study, we performed single-cell RNA sequencing on two clonal CHO-K1 cell populations with different stability phenotypes over a 90 day culture period.

Project description:MicroRNAs are small non-coding RNAs that play a critical role in post-transcriptional control of gene expression. Recent publications of genomic sequencing data from CHO cells provide new tools for the discovery of novel miRNAs in this important production system. The current release of the miRNA registry miRBase contains 307 mature miRNAs and 200 precursor sequences. We searched for evolutionary conserved miRNAs in recently published genomic data, derived from hamster and CHO cells, to further extend the list of known miRNAs. With our approach we could identify several dozens novel miRNAs and verify their expression with multiple next-generation sequencing experiments. In addition, a great amount of unexpressed miRNAs could be found, awaiting further confirmation by testing for their transcription in different Chinese hamster tissues.

Project description:Transcriptomic data from CHO-S cells were gathered from multiple time points during batch culture to provide information about gene presence/absence for generation of a CHO-S cell line specific model using the GIMME algorithm.

Project description:CHO-DG44