Regulating apoptosis in mammalian cell cultures

Cell culture technology has become a widely accepted method used to derive therapeutic and diagnostic protein products. Mammalian cells adapted to grow in bioreactors now play an integral role in the development of these biologicals. A major limiting factor determining the output efficiency of mammalian cell cultures however, is apoptosis or programmed cell death. Methods to delay apoptosis and increase the longevity of cell cultures can lead to more economical processes. Researchers have shown that both genetic and chemical strategies to block apoptotic signals can increase cell culture productivity. Here, we discuss various strategies which have been implemented to improve cellular viabilities and productivities in batch cultures.     

The application of SELDI-TOF mass spectrometry to mammalian cell culture

Surface Enhanced Laser Desorption/Ionisation Time-of-Fight Mass Spectrometry (SELDI-TOF MS) is a technique by which protein profiles can be rapidly produced from a wide variety of biological samples. By employing chromatographic surfaces combined with the specificity and reproducibility of mass spectrometry it has allowed for profiles from complex biological samples to be analysed. Profiling and biomarker identification have been employed widely throughout the biological sciences. To date, however, the benefits of SELDI-TOF MS have not been realised in the area of mammalian cell culture. The advantages in identifying markers for cell stresses, apoptosis and other culture parameters mean that these tools could help greatly to enhance monitoring and control of bioreaction process and improve the production of therapeutics. Better characterisation of culture systems through proteome analysis will allow for improved productivity and better yields.     

Dynamics of recombinant protein production by mammalian cells in immobilized perfusion culture

In spite of the generally stable nature of immobilized perfusion culture, its profile of target protein production frequently shows variations. This might be explained by the drift in the metabolism of cultured cells. To address this issue, we performed a set of four Opticell bioreactor cultures producing recombinant anticogulant protein PCGFX. All the cultures lasted 40-50 days with the oxygen consumption rate (OCR) mostly around 10 μmol min⁻¹; nevertheless, glucose and lactate metabolism was fluctuated with a parallel fluctuation in the recombinant protein productivity (RPP). The mean productivity of recombinant PCGFX was determined to be about 1.0 mg day⁻¹ for all the cultures. The statistical analysis revealed a significant correlation between the lactate production rate (LPR) and RPP in two cultures. A significant correlation was further found between average OCR and RPP in another culture where OCR was exceptionally lowered under serum-free conditions. No parameter significantly correlated with RPP in the remaining one culture; thus, the overt drift of RPP resulted, at least partly, from that of the cell metabolic activity and the present data should be helpful to explore a strategy for maximizing productivity.     

Spectroscopic methods and their applicability for high‐throughput characterization of mammalian cell cultures in automated cell culture systems

The number and use of automated cell culture systems for mammalian cell culture are steadily increasing. Automated cell culture systems require miniaturized analytics with a high throughput to obtain as much information as possible from single experiments. Standard analytics commonly used for conventional bioreactor samples cannot handle the high throughput and the low sample volumes. Spectroscopic methods provide a means of meeting this analytical requirement and afford fast and direct access to process information. In the first part of this review, UV/VIS, fluorescence, Raman, near‐infrared, and mid‐infrared spectroscopy are presented. In the second part of the review, these spectroscopic methods are evaluated in terms of their applicability in the new field of mammalian cell culture processes in automated cell culture systems. Unlike standard bioreactors, these automated systems have special requirements that apply to the use of spectroscopic methods. Therefore, they are compared with regard to cell culture automation, throughput, and required sample volume.     

Albumin and mammalian cell culture: implications for biotechnology applications

Albumin has a long historical involvement in design of media for the successful culture of mammalian cells, in both the research and commercial fields. The potential application of albumins, bovine or human serum albumin, for cell culture is a by-product of the physico-chemical, biochemical and cell-specific properties of the molecule. In this review an analysis of these features of albumin leads to a consideration of the extracellular and intracellular actions of the molecule, and importantly the role of its interactions with numerous ligands or bioactive factors that influence the growth of cells in culture: these include hormones, growth factors, lipids, amino acids, metal ions, reactive oxygen and nitrogen species to name a few. The interaction of albumin with the cell in relation to these co-factors has a potential impact on metabolic and biosynthetic activity, cell proliferation and survival. Application of this knowledge to improve the performance in manufacturing biotechnology and in the emerging uses of cell culture for tissue engineering and stem cell derived therapies is an important prospect.     

工业真菌高效产酶突变技术与高产机制

工业真菌是酶制剂的重要生产微生物,其菌种改良具有重要应用价值。综述了产酶工业真菌的应用、突变育种技术进展和高效产酶机制的分析策略,尤其是基于组学水平的基因组、转录组和蛋白质组的分析等,最后总结了高产机制在菌株改良上的应用。     

Designing a blueprint for next-generation stem cell bioprocessing development

The creation of a blueprint for stem cell bioprocess development that it is easily readable and shareable among those involved in the construction of the bioprocess is a necessary step toward full-fledged bioprocess integration. The blueprint provides the culturing tools and methodologies, designed to highlight knowledge gaps within biological sciences and bioengineering. This review highlights a blueprint for stem cell bioprocessing development using a landscape architecture approach that can aid the development of culture technologies and tools that satisfy the demands for stem cell-derived products for use in clinical and industrial applications. This work is intended to provide insights to cell biologists, geneticists, bioengineers, and clinicians seeking knowledge outside of their field of expertise and fosters a leap from a reductionist approach to one, that is, globally integrated in stem cell bioprocessing.     

Application of Next-generation Sequencing Technology in Forensic Science

Next-generation sequencing （NGS） technology, with its high-throughput capacity and low cost, has developed rapidly in recent years and become an important analytical tool for many genomics researchers. New opportunities in the research domain of the forensic studies emerge by harnessing the power of NGS technology, which can be applied to simultaneously analyzing multi- ple loci of forensic interest in different genetic contexts, such as autosomes, mitochondrial and sex chromosomes. Furthermore, NGS technology can also have potential applications in many other aspects of research. These include DNA database construction, ancestry and phenotypic inference, monozygotic twin studies, body fluid and species identification, and forensic animal, plant and microbiological analyses. Here we review the application of NGS technology in the field of forensic science with the aim of providing a reference for future forensics studies and practice.     

Evaluation of criteria for bioreactor comparison and operation standardization for mammalian cell culture

Development of bioprocesses with mammalian cell culture deals with different bioreactor types and scales. The bioreactors might be intended for generation of cell inoculum and production, research, process development, validation, or transfer purposes. During these activities, not only the difficulty of up and downscaling might lead to failure of consistency in cell growth, but also the use of different bioreactor geometries and operation conditions. In such cases, criteria for bioreactor design and process transfer should be carefully evaluated in order to select appropriate cultivation parameters. In this work, power input, mixing time, impeller tip speed, and Reynolds number have been compared systematically for the cultivation of the human cell line AGE1.HN within three partner laboratories using five different bioreactor systems. Proper operation ranges for the bioreactors were identified using the maximal cell‐specific growth rate (μ_max) as indicator. Common optimum values for process transfer criteria were found in these geometrically different bioreactors, in which deviations of μ_max between cultivation systems can be importantly reduced. The data obtained in this work are used for process standardization and comparability of results obtained in different bioreactor systems, i.e. to guarantee lab‐to‐lab consistency for systems biology approaches using mammalian cells.     

Step-fortifications of nutrients in mammalian cell culture

A series of high-density media for mammalian cell culture were developed by step-fortifications of most nutrient components in RPMI-1640 medium. Each medium constituting the series was constructed to meet in vitro cell growth limitations. Four different cell lines were cultivated in the media series, and their growth characteristics were observed. Maximum cell densities varied in the range of 0.4 to 1.3 x 10(7) cells/mL, depending on cell lines. Cell growth responses to each of the media series were analyzed in terms of cell density and cell mass. Step increases of cell mass in the range of 1.3 to 3.7 g/L were observed according to the step-fortifications of nutrients. Also, the characteristics of each cell line were compared in terms of metabolic yields and specific productions of lactic acid and ammonium ion. The effect of step-fortifications of nutrients on the production of monoclonal antibody was also examined. Apparent differences in metabolic characteristics among cell lines were observed. Experimental results suggested that the different cell sizes and metabolic characteristics of each cell line resulted in cell-line-specific responses to the step-fortifications. The significant influence of nutritional fortifications on high-density culture of mammalian cells was evaluated. (c) 1993 John Wiley & Sons, Inc.     

A GFP-based method facilitates clonal selection of transfected CHO cells

The identification of highly expressing clones is a crucial step in the development of cell lines for production of recombinant proteins. Here we present a method based on the co-expression of enhanced green fluorescent protein (EGFP) that allows clonal selection in standard 96-well cell culture plates. The genes encoding the EGFP protein and the protein of interest are linked by an internal ribosome entry site and thus are transcribed into the same mRNA but are translated independently. Since both proteins arise from a common mRNA, the EGFP expression level correlates with the expression level of the therapeutic protein for each clone. By expressing recombinant growth factors in CHO cells, we demonstrate the robustness and performance of this technique. The method is an alternative to the identification of high-producer clones using various cell sorting methods, as it can be performed with standard laboratory equipment.     

Applying intensified design of experiments to mammalian cell culture processes

The analysis of data collected using design of experiments (DoE) is the current gold standard to determine the influence of input parameters and their interactions on process performance and product quality. In early development, knowledge on the bioprocess of a new product is limited. Many input parameters need to be investigated for a thorough investigation. For eukaryotic cell cultures, intensified DoE (iDoE) has been proposed as efficient tool, requiring fewer bioreactor runs by introducing setpoint changes during the bioprocess. We report the first successful application of iDoE to mammalian cell culture, performing sequential setpoint changes in the growth phase for the selected input parameters temperature and dissolved oxygen. The process performance data were analyzed using ordinary least squares regression. Our results indicate iDoE to be applicable to mammalian bioprocesses and to be a cost‐efficient option to inform modeling early on during process development. Even though only half the number of bioreactor runs were used in comparison to a classical DoE approach, the resulting models revealed comparable input‐output relations. Being able to examine several setpoint levels within one bioreactor run, we confirm iDoE to be a promising tool to speed up biopharmaceutical process development.     

Identification and authentication of animal cell culture by polymerase chain reaction amplification and DNA sequencing

Polymerase chain reaction (PCR) amplification and deoxyribonucleic acid (DNA) sequence analysis were used to identify the species origin of cell lines used in a cell culture facility where various cell lines of different species are routinely propagated. The aldolase gene family was selected for PCR amplification because the DNA sequences of this gene are highly conserved over a wide range of animals and humans. A total of 36 cell lines representing 13 different species were selected for this study. The DNA from each cell line was amplified, and PCR products were analyzed by agarose gel electrophoresis. The results showed unique profiles of amplified bands on agarose gels that allowed differentiation among non-closely related species. However, DNA amplification of closely related species, including rat and mouse or human and primate, resulted in similar and indistinguishable banding patterns that could be further differentiated by DNA sequence analysis. These results suggested that aldolase gene amplification coupled with DNA sequence analysis is a useful tool for identification of cell lines and has potential application for use in identification of interspecies cross-contamination.     

Kinetics of recombinant immunoglobulin production by mammalian cells in continuous culture

A clonal derivative of a transfectant of the SP2/O myeloma cell line producing a chimeric monoclonal antibody was maintained in steady-state, continuous culture at dilution rates ranging from 0.21 to 1.04 day(-1). The steady-state values for nonviable and total cell concentrations increased as the dilution rate decreased, while the viable cell concentration was roughly independent of the dilution rate. At steady state, the specific growth rate increased and the specific death rate decreased as the dilution rate increased. The maximum specific growth rate was 1.15 day(-1). Antibody production was growth associated and the specific rate of antibody production increased linearly as the specific growth rate increased.     

Identification of cell culture conditions to control protein aggregation of IgG fusion proteins expressed in Chinese hamster ovary cells

The presence of aggregated forms of proteins can be problematic for therapeutics due to the potential for immunogenic and pharmacokinetic issues. Although downstream processing can remove the aggregated forms, inhibiting aggregate formation upstream during the cell culture stage could reduce the burden on downstream processing and potentially improve process yields. This study first examined the effects of environmental factors (temperature, pH, and dissolved oxygen) and medium components (bivalent copper ion, cysteine, and cystine) on the aggregation of two different recombinant fusion proteins expressed by Chinese hamster ovary (CHO) cells. Any strategy to reduce protein aggregation upstream during cell culture must also consider potential effects on critical upstream parameters such as cell growth, harvest titer, and protein sialylation levels. Manipulating the culture temperature shift and cystine concentration in the medium were both identified as effective and practical strategies for reducing protein aggregation in both CHO-cell expression systems. Furthermore, a combination of both strategies was more effective in reducing protein aggregation levels compared to either approach individually; and without any negative effects on harvest titer and protein sialylation. This study demonstrates a practical methodology for decreasing protein aggregation during upstream processing and emphasizes the importance of process understanding to ensure production of recombinant glycoprotein therapeutics with consistent product quality.     

大规模动物细胞培养的问题及对策

大规模动物细胞培养在生物技术产业化进程中显示出强大的潜力。本文综述了大规模动物细胞培养过程中出现的问题及其解决办法 ,包括细胞培养环境、基因工程途径改建细胞系及过程监控等。对于这些进展的充分了解对优化细胞培养工艺、提高产品质量具有重要意义     

Proteomic profiling of recombinant cells from large-scale mammalian cell culture processes

Global expression profiling of mammalian cells used for the production of biopharmaceuticals will allow greater insights into the molecular mechanisms that result in a high producing cellular phenotype. These studies may give insights for genetic intervention to possibly create better host cell lines or even to provide clues to more rational strategies for cell line and process development. In this review I will focus on the contribution of proteomic technologies to a greater understanding of the biology of Chinese hamster ovary cells and other producing cell lines such as NS0 mouse cells.