Jordi J. Cairó

Improvement of CHO Cell Culture Medium Formulation: Simultaneous Substitution of Glucose and Glutamine

The formulation of the culture medium for a Chinese hamster ovary (CHO) cell line has been investigated in terms of the simultaneous replacement of glucose and glutamine, the most commonly employed carbon and nitrogen sources, pursuing the objective of achieving a more efficient use of these compounds, simultaneously avoiding the accumulation of lactate and ammonium in the medium. The key factor in this process is the selection of compounds that are slowly metabolized. Among the different compounds studied, galactose and glutamate provide the best results, allowing support of cell growth with an optimal balance between nutrient uptake and cell requirements and the generation of minimal quantities of lactate and ammonium. The attained results also highlight the capacity of the cells to redistribute their metabolism as a response to the changes in medium composition.

Analysis of CHO Cells Metabolic Redistribution in a Glutamate-Based Defined Medium in Continuous Culture

The effect of glutamine replacement by glutamate and the balance between glutamate and glucose metabolism on the redistribution of t‐PA‐producing recombinant CHO cells metabolism is studied in a series of glucose shift down and shift up experiments in continuous culture. These experiments reveal the existence of multiple steady states, and experimental data are used to perform metabolic flux analysis to gain a better insight into cellular metabolism and its redistribution. Regulation of glucose feed rate promotes a higher efficiency of glucose and nitrogen source utilization, with lower production of metabolic byproducts, but this reduces t‐PA specific production rate. This reduction under glucose limitation can be attributed to the fact that the cells are forced to efficiently utilize the carbon and energy source for growth, impairing the production of dispensable metabolites. It is, therefore, the combination of growth rate and carbon and energy source availability that determines the level of t‐PA production in continuous culture.

Effect of aging on the pluripotential capacity of human CD105+ mesenchymal stem cells

Whether aging modifies mesenchymal stem cell (MSC) properties is unknown.

Modification of glucose and glutamine metabolism in hybridoma cells through metabolic engineering

The present work describes the genetic modification of a hybridoma cell line with the aim to change its metabolic behaviour, particularly reducing the amounts of ammonia and lactate produced by the cells. The cellular excretion of ammonia was eliminated by transfection of a cloned glutamine synthetase gene. The metabolic characterisation of the transformed cell line includes the analysis of the changes introduced in its intracellular metabolic fluxes by means of a stoichiometric model. Furthermore, the reduction of lactate accumulation was attempted through an antisense mRNA approach, aiming to generate a rate limiting step in the glycolytic pathway, thus lowering the glucose consumption rate. The physiological results obtained with the transformed cells are discussed. A maximum reduction of about 47% in the glucose consumption rate was obtained for one of the transformations. However a main drawback was the lack of stability of the transformed cells

FGF-4 increases in vitro expansion rate of human adult bone marrow-derived mesenchymal stem cells.

Human bone marrow-derived mesenchymal stem cells (MSCs) exhibit limited in vitro growth. Fibroblast growth factors (FGFs) elicit a variety of biological responses, such as cell proliferation, differentiation and migration. FGF-4 represents one of the FGFs with the highest cell mitogenic activity. We studied the effect of FGF-4 on MSCs growth and pluripotency. MSCs duplication time (Td) was significantly reduced with FGF-4 compared to controls (2.2 ± 0.2 vs. 4.1 ± 0.2 days, respectively; p = 0.03) while BMP-2 and SCF-1 did not exert a significant growth effect. MSC expression of surface markers, differentiation into adipogenic and osteogenic lineages, and baseline expression of cardiomyogenic genes were unaffected by FGF-4. In summary, exogenous FGF-4 increases the rate at which MSC proliferate and has no significant effect on MSC pluripotency.

Metabolic engineering of apoptosis in cultured animal cells: implications for the biotechnology industry.

Animal cells have been widely used to obtain a wide range of products for human and animal healthcare applications. However, the extreme sensitivity of these cells in respect to changes experienced in their environment is evidenced by the activation of a gene-encoded program known as apoptosis, resulting in their death and destruction. From the bioprocess angle, losses in cell viability bring lower productivities and higher risks of product degradation. Consequently, many research efforts have been devoted to the development of apoptosis protective mechanisms, including the metabolic engineering of apoptosis pathways, that has proven effective in diminishing programmed cell death in a variety of biotechnological relevant cell lines. This review is focused especially in the encouraging initial results obtained with the over-expression of cloned anti-apoptosis genes, from both endogenous and viral origin interfering at mitochondrial and initiator caspases levels.

Use of a chronic model of articular cartilage and meniscal injury for the assessment of long-term effects after autologous mesenchymal stromal cell treatment in sheep

Regenerative therapies using adult stem cells have attracted great interest in the recent years and offer a promising alternative to current surgical practices. In this report, we evaluated the safety and efficacy of an autologous cell-based treatment of osteoarthritis using mesenchymal stromal cells expanded from bone marrow aspirates that were administered intra-articularly. Ten 2-year old ewes were divided in two groups (for analysis at 6 and 12 months, respectively). Full thickness articular cartilage defects of approximately 60mm(2) were created arthroscopically in the medial femorotibial condyles and a meniscal tear in the anterior horn of the medial meniscus in the 20 hind legs. Intra-articular injection of 4 mL of either treatment (a suspension of cells) or control (same as treatment, without cells) were applied one month after generating a chronic condition similar to human pathology. Animals were monitored radiographically, by MRI and ultrasound scanning; and macroscopic and histological analyses were conducted at 6 and 12 months. Furthermore a full necropsy was performed at 12 months post-treatment. The intra-articular injection of autologous MSC was safe, as judged by the lack of local or systemic adverse effects during the clinical follow-up and by a full necropsy performed at 12 months post-treatment. Evidence of regeneration of articular cartilage and meniscus was case-dependent but statistically significant improvement was found in specific macroscopic and histological parameters. Such parameters included colour, rigidity, cell distribution and hyaline quality of the refill tissue as well as the structure of subchondral bone.

Electrical impedance spectroscopy measurements using a four-electrode configuration improve on-line monitoring of cell concentration in adherent animal cell cultures.

This paper describes the improvement in the use of electrical impedance spectroscopy (EIS) for animal cell concentration monitoring of adherent cultures by using a four-electrode configuration instead of the commonly used two-electrode configuration. This four-electrode configuration prevents cell concentration measurements from external masking effects such as the electrode covering ratio, the degree of cellular adherence to the electrodes and the impedance of the measuring electrodes. Cell concentration was monitored using both four-electrode and two-electrode configurations in vero cell and human mesenchymal stem cell cultures in order to analyze the attained improvement in two cell lines with opposite growth characteristics. The experiments performed with vero cell cultures evidenced that the four-electrode configuration enables cell concentration measurements along all culture phases, even once the culture reached cell confluence (over 2×10(5) cells/cm(2)), confirming that this configuration is less effected by all the external influences. The experiments performed with human mesenchymal stem cells demonstrated good sensitivity of the measurement at very low cell concentrations, as well as a very good robustness all over the 12-days experiment. Finally, off-line cell measurements during cell cultures proved good accuracy of impedance measurements carried out with a four-electrode configuration along all cell growth phases, enabling determination of relevant cell growth parameters.

Identification of key patterns in the metabolism of hybridoma cells in culture

Abstract In transformed cell lines, glucose and glutamine transport into cells as well as glycolysis and glutaminolysis pathways occur at high rates. As a consequence, cells in culture show a poor exploitation of these resources and produce excessive amounts of lactic acid and ammonium. In this work, a murine hybridoma cell line (KB-26.5) was cultivated in batch cultures with different concentrations of oxamate, an specific inhibitor of lactate dehydrogenase. The results show that the conversion of pyruvate into lactate is absolutely necessary for cell survival as a way to reoxidize the large amounts of NADH produced in the rapid glycolysis; moreover, this metabolic analysis was completed with a continuous culture at changing inlet concentrations of glucose and glutamine. Steady-state viable cell, total cell, glucose, lactate, ammonium glutamine, and other amino acids were measured over a wide range of glucose and glutamine feed concentrations. The results show the metabolic deregulation existing in hybridoma cells and make it possible to calculate the minimal specific requirements for glucose (76.8 nmol 10 6 cells −1 h −1 ) and glutamine (30.72 nmol 10 6 cells −1 h −1 ) to maintain a cell population with minimal excretion of partly oxidized undesirable end products and a minimal increase in osmolarity. An explanation of these metabolic patterns is discussed in terms of NADH regeneration.

Uses of β-galactosidase tag in on-line monitoring production of fusion proteins and gene expression in Escherichia coli

Abstract A simple method for monitoring and quantifying automatically the production by fermentation of β-galactosidase fusion proteins, making use of the remaining activity of the β-galactosidase part, is considered. A hybrid protein carrying the major antigenic domain of foot-and-mouth disease virus C 1 joined at the N-terminus of β-galactosidase has been expressed in Escherichia coli. The yield of the chimeric protein has been monitored by flow injection analysis (FIA) during batch fermentations at laboratory scale, and a high correlation between values of product concentration from FIA and from immunological quantizations has been obtained. Because of the possibility of employing FIA in large-scale experiments, and the high sampling frequency, versatility, and reproducibility offered by this method, we propose FIA as a general, simple, quick, flexible, and reliable instrument for both monitoring the yield of recombinant proteins produced industrially, and performing basic research at laboratory scale.