Regulation of cell proliferation and apoptosis in CHO-K1 cells by the coexpression of c-Myc and Bcl-2

Proliferation and cell death are regarded as key targets for the optimization of animal cell culture processes and for the maximization of product yield. Although chemical and physical factors are vitally important, of primary interest is the utilization of genetic engineering to regulate cellular processes. CHO cells were first genetically modified to enhance proliferation rate in both suspension and monolayer cultures. Under the constitutive control of c-myc overexpression the CHO cultures showed an increase in growth rate and maximum cell number accompanied by a similar decrease in specific glucose consumption rate. Although the c-myc transfected cell line exhibited apoptosis at much lower rates than is widely reported and associated with the overexpression of c-Myc, it was nevertheless apparent that c-Myc was responsible for the induction of higher apoptotic rates when compared with the control cell line. Hence, the anti-apoptotic gene bcl-2 was also used to transfect the c-Myc CHO cell line, to reduce cell death. Overexpression of both oncoproteins resulted in a cell line that exhibited higher proliferation rates and maximum cell numbers, with a decrease in apoptosis when compared to the parental cell line. In conclusion, it was shown that Bcl-2 protein overexpression specifically abrogates c-Myc-induced apoptosis without affecting the c-Myc mitogenic function.     

Attenuating apoptosis in Chinese hamster ovary cells for improved biopharmaceutical production

Chinese hamster ovary (CHO) cells are the predominant host cell line for the production of biopharmaceuticals, a growing industry currently worth more than $188 billion USD in global sales. CHO cells undergo programmed cell death (apoptosis) following different stresses encountered in cell culture, such as substrate limitation, accumulation of toxic by-products, and mechanical shear, hindering production. Genetic engineering strategies to reduce apoptosis in CHO cells have been investigated with mixed results. In this review, a contemporary understanding of the real complexity of apoptotic mechanisms and signaling pathways is described; followed by an overview of antiapoptotic cell line engineering strategies tested so far in CHO cells.     

CHO细胞表达糖蛋白的研究进展*

中国仓鼠卵巢细胞(Chinese hamster ovary cells,CHO)表达系统因具有较高密度培养、高表达和相对完整的蛋白质糖基化修饰系统等特点,成为生产糖蛋白广泛应用的宿主表达细胞之一。目前已产生不同的CHO细胞系和各种功能细胞株以满足对糖蛋白的大量生产和其他实验需求。近年来,随着基因工程、蛋白质工程、细胞工程和发酵调控等技术的发展应用,由CHO细胞生产糖蛋白的产量和糖基化修饰程度取得了突破。然而,随着生物制品市场对于糖蛋白的需求增加,如何获得大量、均质的糖蛋白也成为急需解决的问题。综述了不同工程CHO表达系统的研究、应用、糖基化修饰系统,以及影响外源糖蛋白在CHO系统表达和糖基化修饰的理化因素,结合文献总结并预测了未来CHO细胞表达系统研究的四个具有重大意义的研究方向,以期在未来可以改善由CHO细胞表达糖蛋白的产量和质量。     

CHO microRNA engineering is growing up: Recent successes and future challenges

microRNAs with their ability to regulate complex pathways that control cellular behavior and phenotype have been proposed as potential targets for cell engineering in the context of optimization of biopharmaceutical production cell lines, specifically of Chinese Hamster Ovary cells. However, until recently, research was limited by a lack of genomic sequence information on this industrially important cell line. With the publication of the genomic sequence and other relevant data sets for CHO cells since 2011, the doors have been opened for an improved understanding of CHO cell physiology and for the development of the necessary tools for novel engineering strategies. In the present review we discuss both knowledge on the regulatory mechanisms of microRNAs obtained from other biological models and proof of concepts already performed on CHO cells, thus providing an outlook of potential applications of microRNA engineering in production cell lines.     

Serum protects protein-free competent Chinese hamster ovary cells against apoptosis induced by nutrient deprivation in batch culture.

The development of serum- and protein-free Chinese hamster ovary (CHO) cell cultures is a high priority for the production of biopharmaceuticals. Protein-free competent CHO cells lines have been previously constructed by two different methods-metabolic engineering with cell-cycle regulatory proteins and long-term selective adaptation. Apoptosis was present in both cell lines during protein-free, static-batch culture as a result of nutrient deprivation, and glucose deprivation alone was a potent inducer of apoptosis compared to the depletion of other nutrients such as amino acids. By adding back serum to the cultures during batch growth or nutrient deprivation, it was shown that unidentified survival factors in serum can greatly reduce apoptosis in protein-competent cell lines in all phases of the culture. Both observations contrast to previous reports for hybridoma cells, in which amino acids were the key determinants of apoptosis and serum had no additional antiapoptotic effect. Serum's protective effect against CHO cell death in batch culture was multifaceted and complex: (1) 10% FBS increased cell viability to >99% during exponential growth from roughly 75-90%, (2) 5-10% fetal bovine serum (FBS) reduced specific glucose consumption rates in both cell lines by 40%, thereby delaying the onset of apoptosis caused by glucose deprivation, and (3) 5% FBS reduced the specific cell death rate by 65% during a 3-d lactate-consumption phase characterized by substantial abortive proliferation, in which the cells both proliferated and died at a constant rate. The benefit of serum on cell production over the various phases of batch growth was combined into a single parameter by integrating the viable cell concentration vs. time profile (termed here as cumulative volumetric viable cell-time, VCTvol). Despite the ability of both cell lines to grow indefinitely without any exogenous growth factors, the addition of serum resulted in a 2. 3-fold increase in the VCTvol. Thus, it is clear that there is much room for improvement of protein-free CHO cell lines despite their adequate growth competence, and new strategies different from those successfully used for hybridomas may be necessary to combat CHO cell apoptosis.     

Monitoring of autophagy in Chinese hamster ovary cells using flow cytometry

Recently, autophagy, which is a degradative process, has drawn attention as an anti-cell death engineering target in addition to apoptosis in recombinant Chinese hamster ovary (rCHO) cell cultures for enhanced production of therapeutic proteins. Appropriate autophagy monitoring methods, that are suitable for long term CHO cell cultures, are necessary in order to investigate the culture conditions that affect the autophagy pathway and to select appropriate engineering targets for autophagy control. Herein, detailed protocols for autophagy monitoring methods based on flow cytometry are provided using the GFP-LC3-overexpressing CHO DG44 host cell line or MDC-like molecules in rCHO cells grown as an adherent culture with serum-containing medium or suspension culture with serum-free medium. Furthermore, combined with the apoptosis detection based on the Annexin V-PS interaction, the simultaneous detection of autophagy and apoptosis is also described. It is anticipated that the protocols described herein will assist in the fast, high throughput monitoring of autophagy that can support other existing autophagy assays.     

Profiling highly conserved microrna expression in recombinant IgG‐producing and parental Chinese hamster ovary cells

MicroRNAs (miRNAs) play important roles in global gene regulation. Researchers in recombinant protein production have proposed miRNAs as biomarkers and cell engineering targets. However, miRNA expression remains understudied in Chinese Hamster Ovary cells, one of the most commonly used host cell systems for therapeutic protein production. To profile highly conserved miRNA expression, we used the miRCURY? miRNA array for screening miRNAs in CHO cells. The selection criteria for further miRNA profiling included positive hybridization signals and experimentally validated predicted regulatory targets. On the basis of screening, we selected 16 miRNAs for quantitative RT‐PCR profiling. We profiled miR expression in parental CHO DG44 and CHO K1 cell lines as well as four recombinant DG44‐derived CHO lines producing a recombinant human IgG. We observed that miR‐221 and miR‐222 were significantly downregulated in all IgG‐producing cell lines when compared with parental DG44, whereas miR‐125b was significantly downregulated in one IgG‐producing line. In another IgG‐producing line, miR‐19a was significantly upregulated. miRNA expression was also profiled in two of these lines that were amplified by stepwise increase of methotrexate. In both amplified cell lines, let‐7b and miR‐221 were significantly downregulated. In parental CHO K1, let‐7b, miR‐15b, and miR‐17 were significantly downregulated when compared with DG44. The results reported here are the first steps toward profiling highly conserved miRNAs and studying the clonal difference in miRNA expression in CHO cells and may shed light on using miRNAs in cell engineering. © 2011 American Institute of Chemical Engineers Biotechnol. Prog., 2011     

CRISPR/Cas12a-mediated CHO genome engineering can be effectively integrated at multiple stages of the cell line generation process for bioproduction

Most biopharmaceuticals produced today are generated using Chinese hamster ovary (CHO) cells, therefore significant attention is focused on methods to improve CHO cell productivity and product quality. The discovery of gene-editing tools, such as CRISPR/Cas9, offers new opportunities to improve CHO cell bioproduction through cell line engineering. Recently an additional CRISPR-associated protein, Cas12a (Cpf1), was shown to be effective for gene editing in eukaryotic cells, including CHO. In this study, we demonstrate the successful application of CRISPR/Cas12a for the generation of clonally derived CHO knockout (KO) cell lines with improved product quality attributes. While we found Cas12a efficiency to be highly dependent on the targeting RNA used, we were able to generate CHO KO cell lines using small screens of only 96–320 clonally derived cell lines. Additionally, we present a novel bulk culture analysis approach that can be used to quickly assess CRISPR RNA efficiency and determine ideal screen sizes for generating genetic KO cell lines. Most critically, we find that Cas12a can be directly integrated into the cell line generation process through cotransfection with no negative impact on titer or screen size. Overall, our results show CRISPR/Cas12a to be an efficient and effective CHO genome editing tool.     

Rapamycin treatment inhibits CHO cell death in a serum‐free suspension culture by autophagy induction

Rapamycin, a specific mTOR inhibitor, has been used as a chemical activator in autophagy research both in vitro and in vivo. Recently, autophagy has received attention as an anti‐cell death engineering target in addition to apoptosis in the Chinese hamster ovary (CHO) cell engineering field. Here, the effect of rapamycin and the subsequent autophagy induction is investigated on two CHO cell lines, DG44 host and an antibody‐producing recombinant CHO (rCHO), in a serum‐free suspension culture. In both cell lines, the rapamycin treatment delayed the viability drop and apoptosis induction. In particular, the improved cell viability of the antibody‐producing rCHO cell line resulting from the rapamycin treatment led to a 21% increase in the maximum antibody concentration. From observations that a rapamycin derivative, everolimus, demonstrated similar positive effects in both cell lines, but not FK‐506, which forms the same complex as rapamycin, but does not inhibit mTOR, it was demonstrated that the positive effects of rapamycin appear to be mTOR‐dependent. In addition, the cultivation with rapamycin and/or an autophagy inhibitor, bafilomycin A1, indicated that the autophagy induction is related to the positive effects of rapamycin. The genetic perturbation of the autophagy pathway through the regulation of the expression level of Beclin‐1, an important autophagy regulator, resulted in a delayed autophagy induction and apoptosis inhibition in response to the rapamycin treatment in the DG44 host cell line. Taken together, the results obtained in this study imply a positive role for autophagy and predict the usefulness of pro‐autophagy engineering in CHO cell cultures. Biotechnol. Bioeng. 2012; 109: 3093–3102. © 2012 Wiley Periodicals, Inc.     

A mammalian artificial chromosome engineering system (ACE System) applicable to biopharmaceutical protein production, transgenesis and gene-based cell therapy

Mammalian artificial chromosomes (MACs) provide a means to introduce large payloads of genetic information into the cell in an autonomously replicating, non-integrating format. Unique among MACs, the mammalian satellite DNA-based Artificial Chromosome Expression (ACE) can be reproducibly generated de novo in cell lines of different species and readily purified from the host cells' chromosomes. Purified mammalian ACEs can then be re-introduced into a variety of recipient cell lines where they have been stably maintained for extended periods in the absence of selective pressure. In order to extend the utility of ACEs, we have established the ACE System, a versatile and flexible platform for the reliable engineering of ACEs. The ACE System includes a Platform ACE, containing >50 recombination acceptor sites, that can carry single or multiple copies of genes of interest using specially designed targeting vectors (ATV) and a site-specific integrase (ACE Integrase). Using this approach, specific loading of one or two gene targets has been achieved in LMTK⁻ and CHO cells. The use of the ACE System for biological engineering of eukaryotic cells, including mammalian cells, with applications in biopharmaceutical production, transgenesis and gene-based cell therapy is discussed.     

Transformation of UV-hypersensitive Chinese hamster ovary cell mutants with UV-irradiated plasmids

Transfection of UV-hypersensitive, DNA repair-deficient Chinese hamster ovary (CHO) cell lines and parental, repair-proficient CHO cells with UV-irradiated pHaprt-1 or pSV2gpt plasmids resulted in different responses by recipient cell lines to UV damage in transfected DNA. Unlike results that have been reported for human cells, UV irradiation of transfecting DNA did not stimulate the genetic transformation of CHO recipient cells. In repair-deficient CHO cells, proportionally fewer transformants were produced with increasing UV damage than in repair-proficient cells in transfections with the UV-irradiated hamster adenine phosphoribosyltransferase (APRT) gene contained in plasmid pHaprt-1. However, transfection of CHO cells with UV-irradiated pSV2gpt resulted in neither decline in transformation frequencies in repair-deficient cell lines relative to repair-proficient cells nor stimulation of genetic transformation by UV damage in the plasmid. Blot hybridization analysis of DNA samples isolated from transformed cells showed no dramatic changes in copy number or arrangement of transfected plasmid DNA with increasing UV dose. We conclude that the responses of recipient cells to UV-damaged transfecting plasmids depend both on the type of recipient cell and the characteristics of the genetic sequence used for transfection.     

Autophagy and apoptosis in Chinese hamster ovary cell culture

Upon nutrient deprivation during Chinese hamster ovary (CHO) cell culture for foreign protein production, cells are subjected to two types of programmed cell death (PCD), apoptosis and autophagy. However, only apoptosis has drawn attention in the field of CHO cell culture. Numerous studies on engineering genes or supplementing essential nutrients or chemical additives to culture media to overcome cell death induced by various stimuli have been limited to apoptosis. Recently, autophagic morphologies were demonstrated by the processing of LC3 into the 16 kDa LC3-II form, and the accumulation of multiple autophagosomes in CHO cell culture. Therefore, it seems worthwhile to revisit the issue of cell death in CHO cell culture with the concept of autophagy in mind, in order to achieve a maximum production of foreign proteins by protecting cells from both types of PCD.     

Next-generation sequencing of the Chinese hamster ovary microRNA transcriptome: Identification, annotation and profiling of microRNAs as targets for cellular engineering

Chinese hamster ovary (CHO) cells are the predominant cell factory for the production of recombinant therapeutic proteins. Nevertheless, the lack in publicly available sequence information is severely limiting advances in CHO cell biology, including the exploration of microRNAs (miRNA) as tools for CHO cell characterization and engineering. In an effort to identify and annotate both conserved and novel CHO miRNAs in the absence of a Chinese hamster genome, we deep-sequenced small RNA fractions of 6 biotechnologically relevant cell lines and mapped the resulting reads to an artificial reference sequence consisting of all known miRNA hairpins. Read alignment patterns and read count ratios of 5' and 3' mature miRNAs were obtained and used for an independent classification into miR/miR* and 5p/3p miRNA pairs and discrimination of miRNAs from other non-coding RNAs, resulting in the annotation of 387 mature CHO miRNAs. The quantitative content of next-generation sequencing data was analyzed and confirmed using qPCR, to find that miRNAs are markers of cell status. Finally, cDNA sequencing of 26 validated targets of miR-17-92 suggests conserved functions for miRNAs in CHO cells, which together with the now publicly available sequence information sets the stage for developing novel RNAi tools for CHO cell engineering.     

Mcl‐1 overexpression leads to higher viabilities and increased production of humanized monoclonal antibody in Chinese hamster ovary cells

Bioreactor stresses, including nutrient deprivation, shear stress, and byproduct accumulation can cause apoptosis, leading to lower recombinant protein yields and increased costs in downstream processing. Although cell engineering strategies utilizing the overexpression of antiapoptotic Bcl‐2 family proteins such as Bcl‐2 and Bcl‐x_L potently inhibit apoptosis, no studies have examined the use of the Bcl‐2 family protein, Mcl‐1, in commercial mammalian cell culture processes. Here, we overexpress both the wild type Mcl‐1 protein and a Mcl‐1 mutant protein that is not degraded by the proteasome in a serum‐free Chinese hamster ovary (CHO) cell line producing a therapeutic antibody. The expression of Mcl‐1 led to increased viabilities in fed‐batch culture, with cell lines expressing the Mcl‐1 mutant maintaining ～90% viability after 14 days when compared with 65% for control cells. In addition to enhanced culture viability, Mcl‐1‐expressing cell lines were isolated that consistently showed increases in antibody production of 20–35% when compared with control cultures. The quality of the antibody product was not affected in the Mcl‐1‐expressing cell lines, and Mcl‐1‐expressing cells exhibited 3‐fold lower caspase‐3 activation when compared with the control cell lines. Altogether, the expression of Mcl‐1 represents a promising alternative cell engineering strategy to delay apoptosis and increase recombinant protein production in CHO cells. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

Auditioning of CHO host cell lines using the artificial chromosome expression (ACE) technology

In order to maximize recombinant protein expression in mammalian cells many factors need to be considered such as transfection method, vector construction, screening techniques and culture conditions. In addition, the host cell line can have a profound effect on the protein expression. However, auditioning or directly comparing host cell lines for optimal protein expression may be difficult since most transfection methods are based on random integration of the gene of interest into the host cell genome. Thus it is not possible to determine whether differences in expression between various host cell lines are due to the phenotype of the host cell itself or genetic factors such as gene copy number or gene location. To improve cell line generation, the ACE System was developed based on pre‐engineered artificial chromosomes with multiple recombination acceptor sites. This system allows for targeted transfection and has been effectively used to rapidly generate stable CHO cell lines expressing high levels of monoclonal antibody. A key feature of the ACE System is the ability to isolate and purify ACEs containing the gene(s) of interest and transfect the same ACEs into different host cell lines. This feature allows the direct auditioning of host cells since the host cells have been transfected with ACEs that contain the same number of gene copies in the same genetic environment. To investigate this audition feature, three CHO host cell lines (CHOK1SV, CHO‐S and DG44) were transfected with the same ACE containing gene copies of a human monoclonal IgG1 antibody. Clonal cell lines were generated allowing a direct comparison of antibody expression and stability between the CHO host cells. Results showed that the CHOK1SV host cell line expressed antibody at levels of more than two to five times that for DG44 and CHO‐S host cell lines, respectively. To confirm that the ACE itself was not responsible for the low antibody expression seen in the CHO‐S based clones, the ACE was isolated and purified from these cells and transfected back into fresh CHOK1SV cells. The resulting expression of the antibody from the ACE newly transfected into CHOK1SV increased fivefold compared to its expression in CHO‐S and confirmed that the differences in expression between the different CHO host cells was due to the cell phenotype rather than differences in gene copy number and/or location. These results demonstrate the utility of the ACE System in providing a rapid and direct technique for auditioning host cell lines for optimal recombinant protein expression. Biotechnol. Bioeng. 2009; 104: 526–539 © 2009 Wiley Periodicals, Inc.     

Stable inhibition of mmu-miR-466h-5p improves apoptosis resistance and protein production in CHO cells

MiRNAs have been shown to be involved in regulation of multiple cellular processes including apoptosis. Since a single miRNA can affect the expression of several genes, the utilization of miRNAs for apoptosis engineering in mammalian cells can be more efficient than the conventional approach of manipulating a single gene. Mmu-miR-466h-5p was previously shown to have a pro-apoptotic role in CHO cells by reducing the expression of several anti-apoptotic genes and its transient inhibition delayed both the activation of Caspase-3/7 and the loss of cell viability. The present study evaluates the effect of stable inhibition of mmu-miR-466h-5p in CHO cells on their ability to resist apoptosis onset and their production properties. The expression of mmu-miR-466h-5p in the engineered anti-miR-466h CHO cell line was significantly lower than in the negative control and the parental CHO cells. These engineered cells reached higher maximum viable cell density and extended viability compared with negative control and parental CHO cells in batch cell cultures which resulted in the 53.8% and 41.6% increase of integral viable cells. The extended viability of anti-miR-466h CHO cells was the result of delayed Caspase-3/7 activation by more than 35 h, and the increased levels of its anti-apoptotic gene targets (smo, stat5a, dad1, birc6, and bcl2l2) to between 2.1- and 12.5-fold compared with the negative control CHO in apoptotic conditions. The expression of secreted alkaline phosphatase (SEAP) increased 43% and the cell-specific productivity increased 11% in the stable pools of anti-miR-466h CHO compared with the stable pools of negative control CHO cells. The above results demonstrate the potential of this novel approach to create more productive cell lines through stable manipulation of specific miRNA expression.     

A functional high‐content miRNA screen identifies miR‐30 family to boost recombinant protein production in CHO cells

The steady improvement of mammalian cell factories for the production of biopharmaceuticals is a key challenge for the biotechnology community. Recently, small regulatory microRNAs (miRNAs) were identified as novel targets for optimizing Chinese hamster ovary (CHO) production cells as they do not add any translational burden to the cell while being capable of regulating entire physiological pathways. The aim of the present study was to elucidate miRNA function in a recombinant CHO‐SEAP cell line by means of a genome‐wide high‐content miRNA screen. This screen revealed that out of the 1, 139 miRNAs examined, 21% of the miRNAs enhanced cell‐specific SEAP productivity mainly resulting in elevated volumetric yields, while cell proliferation was accelerated by 5% of the miRNAs. Conversely, cell death was diminished by 13% (apoptosis) or 4% (necrosis) of all transfected miRNAs. Besides these large number of identified target miRNAs, the outcome of our studies suggest that the entire miR‐30 family substantially improves bioprocess performance of CHO cells. Stable miR‐30 over expressing cells outperformed parental cells by increasing SEAP productivity or maximum cell density of approximately twofold. Our results highlight the application of miRNAs as powerful tools for CHO cell engineering, identified the miR‐30 family as a critical component of cell proliferation, and support the notion that miRNAs are powerful determinants of cell viability.