Effect of Nitrogen, Phosphorous, and Light Colimitation on Amphidinol Production and Growth in the Marine Dinoflagellate Microalga Amphidinium carterae.

The marine dinoflagellate microalga Amphidinium carterae is a source of amphidinols, a fascinating group of polyketide metabolites potentially useful in drug design. However, Amphidinium carterae grows slowly and produces these toxins in tiny amounts, representing a hurdle for large-scale production. Understanding dinoflagellate growth kinetics under different photobioreactor conditions is imperative for promoting the successful implementation of a full-scale integrated bioproduct production system. This study evaluates the feasibility of growing Amphidinium carterae under different ranges of nitrogen concentration (NO3- = 882-2646 µM), phosphorus concentration (PO33- = 181-529 µM), and light intensity (Y0 = 286-573 µE m-2 s-1) to produce amphidinols. A mathematical colimitation kinetic model based on the "cell quota" concept is developed to predict both algal growth and nutrient drawdown, assuming that all three variables (nitrogen, phosphorous and light) can simultaneously colimit microalgal growth. The model was applied to the semicontinuous culture of the marine microalgae Amphidinium carterae in an indoor LED-lit raceway photobioreactor. The results show that both growth and amphidinol production strongly depend on nutrient concentrations and light intensity. Nonetheless, it was possible to increase Amphidinium carterae growth while simultaneously promoting the overproduction of amphidinols. The proposed model adequately describes Amphidinium carterae growth, nitrate and phosphate concentrations, and intracellular nitrogen and phosphorus storage, and has therefore the potential to be extended to other systems used in dinoflagellate cultivation and the production of bioproducts obtained therein.

Characterization of bubble column photobioreactors for shear-sensitive microalgae culture.

The shear-sensitive marine algal dinoflagellate Karlodinium veneficum was grown in a cylindrical bubble column photobioreactor with an internal diameter of 0.044 m. Initial liquid height varied from 0.5 to 1.75 m, superficial gas velocities from 0.0014 to 0.0057 ms-1, and nozzle diameter from 1 to 2.5 mm. Computational fluid dynamics was used to characterize the flow hydrodynamics and energy dissipation rates. Experimental gas holdup and volumetric mass transfer coefficient strongly depended on the liquid height and correlated well with the Froude number. Energy dissipation near the head space (EDtop) was one order of magnitude higher than the average energy dissipation in the whole reactor (EDwhole), and the value in the sparger zone (EDspar) was one order of magnitude higher than EDtop. Cultures of K. veneficum were limited by CO2 transfer at low EDwhole and severely stressed above a critical value of EDwhole.

The use of an artificial neural network to model the infection strategy for baculovirus production in suspended insect cell cultures.

Since the infection strategy in the baculovirus-insect cell system mostly affects production of the vector itself or the target product, and given that individual infection parameters interact with each other, the optimal combination must be established for each such specific system. In this work an artificial neural network was used to model infection strategy, including the cell concentration at infection, the multiplicity of infection, the medium recycle, and agitation intensity, and to evaluate the relative importance of each factor in the baculovirus production obtained. The results demonstrate that this model can be used to select an optimal infection strategy. For the baculovirus-insect cell system used in this study, this includes low multiplicity of infection and agitation intensity, along with high cell concentration at infection and medium recycle. Our model is superior to regression methods and predicts baculovirus production more precisely, thus meaning that it could be useful for the development of feasible processes, thereby improving process performance and economy.

Modeling shear-sensitive dinoflagellate microalgae growth in bubble column photobioreactors.

The shear-sensitive dinoflagellate microalga Karlodinium veneficum was grown in a sparged bubble column photobioreactor. The influence of mass transfer and shear stress on cell growth and physiology (concentration of reactive oxygen species, membrane fluidity and photosynthetic efficiency) was studied, and a model describing cell growth in term of mass transfer and culture parameters (nozzle sparger diameter, air flow rate, and culture height) was developed. The results show that mass transfer limits cell growth at low air-flow rates, whereas the shear stress produced by the presence of bubbles is critically detrimental for air flow rates above 0.1vvm. The model developed in this paper adequately represents the growth of K. veneficum. Moreover, the parameters of the model indicate that bubble rupture is much more harmful for cells than bubble formation.

The effect of spent medium recycle on cell proliferation, metabolism and baculovirus production by the lepidopteran Se301 cell line infected at very low MOI.

The aim of this paper was to study the effect of spent medium recycle on Spodoptera exigua Se301 cell line proliferation, metabolism, and baculovirus production when grown in batch suspension cultures in Ex-Cell 420 serum-free medium. The results showed that the recycle of 20% of spent medium from a culture in mid-exponential growth phase improved growth relative to a control culture grown in fresh medium. Although both glucose and glutamine were still present at the end of the growth phase, glutamate was always completely exhausted. The pattern of the specific glucose and lactate consumption and production rates, as well as the specific glutamine and glutamate consumption rates, suggests a metabolic shift at spent medium recycle values of over 60%, with a decrease in the efficiency of glucose utilization and an increase in glutamate consumption to fuel energy metabolism. Baculovirus infection provoked a change in the metabolic pattern of Se301 cells, although a beneficial effect of spent medium recycle was also observed. Both growth rate and maximum viable cell density decreased relative to uninfected cultures. The efficiency of glucose utilization was dramatically reduced in those cultures containing the lowest percentages of spent medium, whereas glutamine and glutamate consumption was modulated, thereby suggesting that infected cells were devoted to virus replication, retaining their ability to incorporate the nutrients required to support viral replication. Recycle of 20% of spent medium increased baculovirus production by around 90%, thus showing the link between cell growth and baculovirus production.

Co-culture of the 55-6 B cell hybridoma with the EL-4 thymoma cell. Effect on cell growth and monoclonal antibody production.

The cell growth and monoclonal antibody production of the 55-6 hybridoma cell co-cultured with the murine thymoma cell line EL-4 at different initial 55-6:EL-4 ratios were investigated. Both populations were seeded in co-culture without previous stimulation and therefore with low constitutive CD40 and CD40 ligand (CD154) expression levels, and in the absence of exogenous co-stimuli. Viable cell density and growth rate data seem to suggest a competition for nutrients, which is detrimental for both cells in terms of biomass production and also of growth rate for 55-6. Final concentrations of antibody and specific antibody production rates were affected by the initial 55-6:EL-4 ratio. The 4:1 ratio yielded the highest IgG2a concentration, whereas the highest specific antibody production rate was obtained at the 2:1 ratio. Changes mainly in CD154 and also in CD40 expression in co-cultures could suggest cross-talk between both populations. In conclusion, different types of interactions are probably present in this co-culture system: competition for nutrients, cognate interaction and/or autocrine or paracrine interactions that influence the proliferation of both cells and the hybridoma antibody secretion. We are hereby presenting a pre-scale-up process that could speed up the optimization of large-scale monoclonal antibodies production in bioreactors by emulating the in vivo cell-cell interaction between B and T cells without previous stimulation or the addition of co-stimulatory molecules.

Effects of hydroxyurea on monoclonal antibody production induced by anti-mIgG and LPS stimulation on murine B cell hybridomas.

Chemical treatment with hydroxyurea (HU) has been selected as a simple and low cost strategy to generate a cell population enriched for the G1 phase. After the chemical treatment with HU, cells were stimulated with anti-mIgG to test if the positive effects of anti-mIgG on CD40 expression and specific IgG2a production rate were improved upon a cell population with a higher percentage of cells in G1 phase at the beginning of the cell culture. In addition, other treatments assayed in this work were the cell stimulation with Lipopolysaccharide (LPS) both before and after the HU treatment. It has been observed that the use of HU under conditions able to maintain the cells in viable state (0.1 mM for 20 h), has a negative effect on CD40 expression and specific IgG2a production rate induced by anti-mIgG. The positive effect of LPS on cell stimulation induced by anti-mIgG is reduced on cells treated with HU.

Enhanced monoclonal antibody production in hybridoma cells by LPS and Anti-mIgG.

This paper reports on a methodology for increasing proliferation and monoclonal antibody (mAb) production in hybridoma cultures. The 55-6 murine B cell hybridoma line (CD40 and CD19-deficient expression) was treated with increasing concentrations of lipopolysaccharide (LPS). Expression of CD69, CD40, and CD19 surface antigens on 55-6 cells did not show significant changes from untreated cells. The specific growth rate decreased at higher concentrations of LPS, but the monoclonal antibody production rate was highest at the highest LPS concentration assayed. These data are in agreement with the lowest growth rate found at this concentration of LPS. Furthermore, cells were cultured with anti-mouse surface immunoglobulin G antibody (anti-mIgG) plus LPS to find out whether LPS-derived signals and anti-mIgG stimuli are synergistic. CD69, CD40, and CD19 expression was greater than for either untreated cells (control culture) or cells stimulated with LPS alone. Moreover, LPS stimulation in combination with anti-mIgG enhanced both the growth rate and IgG2a production over the control culture and cells stimulated with LPS alone. Maximum antibody concentration increased almost 500% compared to the control and about 100% with respect to culture stimulated with LPS alone. The maximum specific IgG2a production rate was about 300% higher than in the control culture and about 30% higher than in culture stimulated only with LPS.

Effects of synchronization on CD40 expression and antibody production in hybridoma cells stimulated with anti-mIgG.

In previous experiments with the 55-6 hybridoma cell line, we showed that cell stimulation with anti-mouse surface immunoglobulin G antibody (anti-mIgG) increased both CD40 expression and specific monoclonal antibody (mAb) production rate. Cell preincubation with lipopolysaccharide (LPS) prior to anti-mIgG stimulation enhanced these results. Moreover, the expression of both CD40 and surface immunoglobulin G (sIgG) were higher for cells in the G1 phase of the cell cycle. Therefore, to determine the relationship between cell cycle position, CD40 expression, and mAb productivity, in this work cells were synchronized in the G1 phase by thymidine block. In addition, synchronized cells were subjected to different treatments with anti-mIgG. Although synchronized cells showed a slight increase in both CD40 expression and maximum specific growth rate (mu max) compared with unsynchronized cells, specific productivity did not show significant changes. However, the stimulation of synchronized cells with anti-mIgG increased over 65% the expression of CD40 and over 50% the specific productivity in comparison with that obtained on unsynchronized cells after anti-mIgG stimulation. These data improved additionally over 15 and 60%, respectively, by adding 2 mM thymidine to the culture medium. These results suggest that the effect of the positive association between G1 phase, CD40 expression, and specific productivity is subordinated to the effect of anti-mIgG stimulation, which is enhanced by increasing the percentage of cells on the G1 phase of the cell cycle. Contrary to expectations, LPS preincubation of synchronized cells prior to anti-mIgG stimulation did not increase the specific productivity in comparison with non-preincubated cells, and the expression of CD40 was minor compared to that on non-preincubated cells.

Induction of CD40 expression and enhancement of monoclonal antibody production on murine B cell hybridomas by cross-linking of IgG receptors.

The 55-6 murine B cell hybridoma line not constitutively expressing CD40 was treated with increasing amounts of intact anti-mouse surface immunoglobulin G antibody (anti-mIgG) either not preincubated or preincubated for 48 h with lipopolysaccharide (LPS). In vitro, cross-linking of surface immunoglobulin G (sIgG) with the whole molecule of anti-IgG antibodies induced the expression of CD69, CD40, and CD19 surface antigens on 55-6 cells. The effect of sIgG ligation was dose-dependent, and preincubation with LPS enhanced their responsiveness to anti-mIgG stimulation. The expression of these surface molecules reached the maximum value during the first part of the cell cycle, corresponding to the position of the G1 peak of the DNA distribution. Stimulation of cells with anti-mIgG did not induce changes either in the number of viable cells or in the fraction of cells undergoing proliferation (mitosis). However, preincubation of 55-6 cells with LPS for 48 h before stimulation with anti-mIgG increased both the maximum specific growth rate (micromax) and the percentage of cells in the G2/M phase, in comparison with non-preincubated cells. Moreover, on cells preincubated with LPS prior to anti-mIgG treatment, specific IgG2a production rate was enhanced significantly compared to that obtained in control cultures. The correlation between the antibody production rate and the amount of IgG that is detectable on the cell surface was analyzed by flow cytometry. A good correlation between secreted and surface IgG was observed, and the results of cell cycle analyses demonstrated that the 55-6 hybridoma cell line has a substantially higher sIgG content in G1 phase.

Producing drugs from marine sponges.

Marine sponges are potential sources of many unique metabolites, including cytotoxic and anticancer compounds. Natural sponge populations are insufficient or inaccessible for producing commercial quantities of metabolites of interest. This review focuses on methods of producing sponge biomass to overcome supply limitations. Production techniques discussed include aquaculture in the sea, the controlled environments of aquariums, and culture of sponge cells and primmorphs. Cultivation in the sea and aquariums are currently the only practicable and relatively inexpensive methods of producing significant quantities of sponge biomass. In the future, metabolite production from cultured sponge cells and primmorphs may become feasible. Obtaining a consistent biomass yield in aquariums requires attention to many factors that are discussed in this work.