The glycosylation of anti-rhIFN-α2b recombinant antibodies influences the antigen-neutralizing activity.

OBJECTIVES: The influence of glycosylation on the antigen-neutralizing ability of two potential biotherapeutic anti-human IFN-α2b antibodies composed by murine and humanized single-chain Fv fused to human Fcγ1 (chimeric and humanized scFv-Fc, respectively) was studied. RESULTS: Chimeric antibodies produced in CHO-K1 and HEK293 mammalian cells showed no differences in the antigen-antibody affinity but demonstrated differences in the in vitro neutralization of IFN-α2b activity. On the other hand, the humanized antibodies produced in the same cell types showed differences in both the antigen-antibody affinity and the antigen-neutralizing ability. These differences are due to the scFv domain, as evidenced by its expression in CHO-K1 and HEK293 cells. In order to determine if the Fc glycosylation influences the antigen binding ability, both parameters were analyzed on chimeric and humanized deglycosylated scFv-Fc. Surprisingly, no differences in the antigen-antibody affinity were observed, but differences in the antigen-neutralizing ability of both chimeric and humanized antibodies, and their respectively deglycosylated glycoforms were found. CONCLUSIONS: Fc glycosylation influences the antigen neutralization ability of two anti-rhIFN-α2b recombinant antibodies. Although affinity is the widely accepted parameter to analyze antibody antigen binding, it does not appear to be sufficient to describe the behavior of recombinant antibodies in vitro. This work contributes with a high impact knowledge to develop therapeutic recombinant antibodies where glycosylation and producer cell lines must be taken into account for their influence on the antigen binding capacity and not only for their impact on the effector properties as it has been historically considered for antibodies.

Recombinant human follicle stimulating hormone purification by a short peptide affinity chromatography.

Peptide KVPLITVSKAK was selected to design a synthetic ligand for affinity chromatography purification of recombinant human follicle stimulating hormone (rhFSH), based on the interaction of the hormone with the exoloop 3 of its receptor. The peptide was acetylated to improve its stability to degradation by exopeptidases. A cysteine was incorporated at the C-termini to facilitate its immobilization to the chromatographic activated SulfoLink agarose resin. A sample of crude rhFSH was loaded to the affinity column, using 20 mM sodium phosphate, 0.5 mM methionine, and pH 5.6 and 7.2 as adsorption and elution buffers, respectively. The dynamic capacity of the matrix was 54.6 mg rhFSH/mL matrix and the purity 94%. The percentage of oxidized rhFSH was 3.4%, and that of the free subunits was 1.2%, both in the range established by the European Pharmacopeia, as also were the sialic acid content and the isoforms profile.

Single step recombinant human growth hormone (rhGH) purification from milk by peptide affinity chromatography.

Recombinant human growth hormone (rhGH) is used for the treatment of several pathologies, most of them related to growth. Although different expression systems can be used for its production, the milk from transgenic cows is one of the most interesting due to the high rhGH level achieved (5 g/L). We have designed and synthesized short peptides (9 or 10 amino acid long) using Fmoc chemistry and studied their ability to purify rhGH from milk once immobilized on an agarose support. Using spiked milk with the hormone as a sample, rhGH was purified with 88% yield and 92% purity in a single step with a fold purification of 4.5. © 2018 American Institute of Chemical Engineers Biotechnol. Prog., 34:999-1005, 2018.

Alternating flow filtration as an alternative to internal spin filter based perfusion process: Impact on productivity and product quality.

This article reports the results obtained from comparison of internal spin filter (ISF) and alternating flow filtration (ATF) as cell retention systems, regarding cell growth, volumetric perfusion rate, cell specific perfusion rate and cell productivity in the fermentation process. As expected we were able to reach higher cell densities and to achieve longer runs since ATF systems are known to be less affected by fouling. Volumetric production of the reactor using the ATF system was 50-70% higher than the production achieved using the ISF due to higher cell density and a two-fold increase in the perfusion rate. On the other hand, downstream processing performances were evaluated regarding chromatographic steps yields and productivity and quality attributes of the purified materials. Similar results were obtained for all evaluated systems. The fact that we were able to achieve a 2 working volumes (WV)/day perfusion rate using an ATF system as cell retention device allowed us to virtually double the WV of a 25 L reactor. These results constitute valuable data for the optimization of recombinant protein production in perfusion processes since a two-fold increase in the average production of a manufacturing facility could be easily achieved as long as downstream scale up is possible. © 2017 American Institute of Chemical Engineers Biotechnol. Prog., 33:1010-1014, 2017.

Glycosylation and antiproliferative activity of hyperglycosylated IFN-α2 potentiate HEK293 cells as biofactories.

Both CHO and HEK cells are interesting hosts for the production of biotherapeutics due to their ability to introduce post-translational modifications such as glycosylation. Even though oligosaccharide structures attached to proteins are conserved among eukaryotes, many differences have been found between therapeutic glycoproteins expressed in hamster and human derived cells. In this work, a hyperglycosylated IFN-α2b mutein (IFN4N) was produced in CHO and HEK cell lines and an extensive characterization of their properties was performed. IFN4NCHO exhibited a higher average molecular mass and more acidic isoforms compared to IFN4NHEK. In agreement with these results, a 2-times higher sialic acid content was found for IFN4NCHO in comparison with the HEK-derived protein. This result was in agreement with monosaccharide quantification and glycan's analysis using WAX chromatography and HILIC coupled to mass spectrometry; all methods supported the existence of highly sialylated and also branched structures for IFN4NCHO glycans, in contrast with smaller and truncated structures among IFN4NHEK glycans. Unexpectedly, those remarkable differences in the glycosylation pattern had not a considerable impact on the clearance rate of both molecules in rats. In fact, although IFN4NHEK reached maximum plasma concentration 3-times faster than IFN4NCHO, their elimination profile did not differ significantly. Also, despite the in vitro antiviral specific biological activity of both proteins was the same, IFN4NHEK was more efficient as an antiproliferative agent in different tumor-derived cell lines. Accordingly, IFN4NHEK showed a higher in vivo antitumor activity in animal models. Our results show the importance of an appropriate host selection to set up a bioprocess and potentiate the use of HEK293 cells for the production of a new hyperglycosylated protein-based pharmaceutical.

Rational selection of an antibody probe to detect the heterogeneous collection of CHO-derived rhGM-CSF glycoforms.

Six anti-E. coli rhGM-CSF monoclonal antibodies were generated using hybridoma technology. One of these showed identical affinity for the CHO and E. coli-derived cytokine (dissociation constants of 0.14 +/- 0.01 nM and 0.13 +/- 0.01 nM, respectively), mapping an epitope that is not hindered by carbohydrates. The antibody was used to develop a simple, specific and sensitive competitive ELISA to quantify the entire set of rhGM-CSF glycoforms (detection limit of 780 pg/ml) and it was successful as an affinity ligand to purify them. Therefore, this particular antibody is a useful, reliable and reagent for most immunochemical purposes with the aim of detecting, quantifying and purifying the highly heterogeneous collection of the CHO-derived rhGM-CSF isoforms.

Temperature reduction in cultures of hGM-CSF-expressing CHO cells: effect on productivity and product quality.

We have demonstrated that temperature reduction from 37 to 33 degrees C in the culture of a CHO cell line producing recombinant human granulocyte macrophage colony stimulating factor (CHO-K1-hGM-CSF) leads to a reduced growth rate, increased cell viability, improved cellular productivity, and decreased cell metabolism. In the present study, CHO-K1-hGM-CSF cells were cultured in a biphasic mode: first, a 37 degrees C growth phase for achieving a high cell number, followed by a production phase where the culture temperature was shifted to 33 degrees C. The maximum cell density was not affected after temperature reduction while cell viability remained above 80% for a further 3.7 days in the culture kept at the lower temperature, when compared to the control culture maintained at 37 degrees C. Furthermore, the total rhGM-CSF production increased 6 times in the culture shifted to 33 degrees C. Because the quality and hence the in vivo efficacy of a recombinant protein might be affected by numerous factors, we have analyzed the N- and O-glycosylation of the protein produced under both cell culture conditions using high-pH anion-exchange chromatography and complementary mass spectrometry techniques. The product quality data obtained from the purified protein preparations indicated that decreasing temperature had no significant effect on the rhGM-CSF glycosylation profiles, including the degree of terminal sialylation. Moreover, both preparations exhibited the same specific in vitro biological activity. These results revealed that the employed strategy had a positive effect on the cell specific productivity of CHO-K1-hGM-CSF cells without affecting product quality, representing a novel procedure for the rhGM-CSF production process.

Establishment of a design space for biopharmaceutical purification processes using DoE.

Recent trends in the pharmaceutical sector are changing the way protein purification processes are designed and executed, moving from operating the process in a fixed point to allowing a permissible region in the operating space known as design space. This trend is driving product development to design quality into the manufacturing process (Quality by Design) and not to rely exclusively on testing quality in the product. A typical purification step has numerous operating parameters that can impact its performance. Therefore, optimization and robustness analysis in purification processes can be time-consuming since they are mainly grounded on experimental work. A valuable approach consists in the combination of an adequate risk analysis technique for selecting the relevant factors influencing process performance and the design of experiment methodology. The latter allows for many process variables which can be studied at the same time; thus, the number of tests will be reduced in comparison with the conventional approach based on trial and error. These multivariate studies permit a detailed exploration in the experimental range and lay the foundation of Quality by Design principles application. This article outlines a recommended sequence of activities toward the establishment of an expanded design space for a purification process.

Determination of robustness and optimal work conditions for a purification process of a therapeutic recombinant protein using response surface methodology.

A typical chromatographic purification step has numerous operating parameters that can impact its performance. As it is not feasible to evaluate the influence of each one, the current practice in biopharmaceutical industry is to apply risk analysis approach to identify process parameters that should be examined during process characterization. Once these parameters are identified, a response surface study can be run to help understand the relationship between critical inputs and outputs. We performed a study comprising optimization and robustness determination for a Blue-Sepharose purification step of rhEPO, a well-known therapeutic glycoprotein. Initially, risk analysis was fulfilled to identify key parameters. A small-scale model was created and qualified before its use in experimental studies, given by a Box-Behnken design with three factors. This method proved to be a very useful tool in bioprocess validation studies in which many input variables can affect product quality and safety.

Statistical optimization of influenza H1N1 production from batch cultures of suspension Vero cells (sVero).

Efficient vaccine production requires the growth of large quantities of virus produced with high yield from a safe host system. Human influenza vaccines are produced in embryonated chicken eggs. However, over the last decade many efforts have allowed the establishment of cell culture-derived vaccines. We generated a Vero cell line adapted to grow in suspension (sVero) in a serum-free medium and evaluated it for its potential as host cell for influenza vaccine production. Initially we studied the capacity of sVero cells to grow in the presence of incremental concentrations of trypsin. In comparison with adherent Vero cells (aVero), we found that sVero cells maintain their growth kinetics even with a three-fold increase in trypsin concentration. The influence of the conditions of infection on the yield of H1N1 produced in serum-free suspension cultures of sVero cells was investigated by a 2(2) full factorial experiment with center point. Each experiment tested the influence of the multiplicity of infection (m.o.i.) and trypsin concentration, on production yields at two levels, in four possible combinations of levels and conditions, plus a further combination in which each condition was set in the middle of its extreme levels. On the basis of software analysis, a combination of m.o.i. of 0.0066TCID(50%)/cell and trypsin concentration of 5µg/1.0×10(6) cells with a desirability of 0.737 was selected as the optimized condition for H1N1 production in sVero cells. Our results show the importance of proper selection of infection conditions for H1N1 production on sVero cells in serum-free medium.

Isolation and characterization of a subset of erythropoietin glycoforms with cytoprotective but minimal erythropoietic activity.

Although historically used for the treatment of anemia, erythropoietin (EPO) has emerged as a neurotrophic and neuroprotective agent in different conditions of neuronal damage (traumatic brain injury, ischemia, spinal cord compression, peripheral neuropathy, retinal damage, epilepsy, Parkinson's Disease, among others). Nonetheless, EPO's therapeutic application is limited due to its hematological side-effects. With the aim of obtaining EPO derivatives resembling the hormone isolated from cells and tissues of neural origin, a novel combination of less acidic EPO glycoforms -designated as neuroepoetin (rhNEPO)- was purified to homogeneity from the supernatant of a CHO-producing cell line by a four-step chromatographic procedure. This simple and single process allowed us to prepare two EPO derivatives with distinct therapeutic expectations: the hematopoietic version and a minimally hematopoietic, but mainly in vitro cytoprotective, alternative. Further biological characterization showed that the in vivo erythropoietic activity of rhNEPO was 25-times lower than that of rhEPO. Interestingly, using different in vitro cytoprotective assays we found that this molecule exerts cytoprotection equivalent to, or better than, that of rhEPO in cells of neural phenotype. Furthermore, despite its shorter plasma half-life, rhNEPO was rapidly absorbed and promptly detected in the cerebrospinal fluid after intravenous administration in rats (5 min postinjection, in comparison with 30 min for rhEPO). Therefore, our results support the study of neuroepoetin as a potential drug for the treatment of neurological diseases, combining high cytoprotective activity with reduced hematological side-effects.

Suspension-Vero cell cultures as a platform for viral vaccine production.

Since Vero cells are currently considered as an acceptable cell substrate to produce a wide range of viruses, we developed a virus production platform using Vero cells adapted to grow in suspension in serum-free media. After adapting anchorage-dependent Vero cells to grow as a free-cell suspension, vesicular stomatitis virus, herpes simplex virus 1 and polio virus 1 production rates were evaluated in batch cultures using spinner flasks and perfused cultures in a bioreactor. The achieved results constitute valuable information for the development of a low-cost high-productivity process using a suspension culture of Vero cells to produce viral vaccines.

Novel chemometric strategy based on the application of artificial neural networks to crossed mixture design for the improvement of recombinant protein production in continuous culture.

The optimal blends of six compounds that should be present in culture media used in recombinant protein production were determined by means of artificial neural networks (ANN) coupled with crossed mixture experimental design. This combination constitutes a novel approach to develop a medium for cultivating genetically engineered mammalian cells. The compounds were collected in two mixtures of three elements each, and the experimental space was determined by a crossed mixture design. Empirical data from 51 experimental units were used in a multiresponse analysis to train artificial neural networks which satisfy different requirements, in order to define two new culture media (Medium 1 and Medium 2) to be used in a continuous biopharmaceutical production process. These media were tested in a bioreactor to produce a recombinant protein in CHO cells. Remarkably, for both predicted media all responses satisfied the predefined goals pursued during the analysis, except in the case of the specific growth rate (mu) observed for Medium 1. ANN analysis proved to be a suitable methodology to be used when dealing with complex experimental designs, as frequently occurs in the optimization of production processes in the biotechnology area. The present work is a new example of the use of ANN for the resolution of a complex, real life system, successfully employed in the context of a biopharmaceutical production process.

N- and O-linked carbohydrates and glycosylation site occupancy in recombinant human granulocyte-macrophage colony-stimulating factor secreted by a Chinese hamster ovary cell line.

GM-CSF is one of several naturally occurring glycoproteins that regulate leukocyte production, migration and function. It has been produced in different cell types, with different properties that depend on the production process used. The purpose of this work was to characterize the recombinant human GM-CSF from an engineered Chinese hamster ovary cell line grown in suspension and as adherent culture for the identification of the glycosylation sites and the definition of the glycosidic moiety, including the degree of site occupancy. Both preparations exhibited size heterogeneity in SDS/PAGE with multiple bands containing glycoprotein forms with either two or one N-glycosylation sites occupied. Minor low molecular mass forms completely lacked N-linked oligosaccharides but contained 1-3 O-linked glycans. Twelve differently charged isoforms were detected in isoelectric focusing gels. At least 16 glycoforms, differing in the number of Hex-HexNAc units (Deltam 365 Da), were detected in MALDI-TOF MS spectra of the desialylated GM-CSFs. MALDI-TOF MS and HPAEC-PAD analysis indicated the presence of predominantly tri- and tetraantennary N-linked oligosaccharide chains with and without N-acetyllactosamine repeat units and some 10% of biantennary oligosaccharides, all containing more than 90% proximal alpha1-6-linked fucose. The oligosaccharide patterns of both GM-CSF preparations were found to be very similar. More than 90% of terminal galactose residues of the N-glycans were found alpha2-3 sialylated with NeuNAc (93%) or NeuNGc (7%). Site specific glycosylation was analysed by electrospray ionization MS and it was found that in the mono glycosylated GM-CSF form more than 90% of the Asn37 were occupied by N-glycans. O-glycosylation at the N-terminus of the polypeptide was detected at Ser7 and Ser9 or Thr10, in the predominantly doubly O-glycosylated glycoprotein form. In the triply modified GM-CSF molecules, Ser5 was additionally O-glycosylated. The major difference between both preparations was found in the MALDI spectra of the desialylated glycoproteins, revealing a higher proportion of forms with a single N-glycosylation site occupied in the preparation derived from suspension culture. ESI-MS and MALDI-MS analysis of endoproteolytically cleaved peptides as well as MALDI-TOF MS of the intact glycoprotein demonstrated the N- and C-termini integrity of the GM-CSF preparations.

Recombinant human granulocyte-macrophage colony-stimulating factor: effect of glycosylation on pharmacokinetic parameters

The pharmacokinetic behaviour of the non-glycosylated, bacterially-derived recombinant human granulocyte-macrophage colony-stimulating factor (rhGM-CSF) and the glycosylated mammalian product was studied after intra and extra vascular administration of a single dose in rodents. Each route of administration gave a different rhGM-CSF concentration-time profile. After extra vascular administration of equivalent doses, a higher peak concentration and faster elimination were observed in the group treated with the E. coli-derived cytokine. The faster elimination resulted in a return to pre-treatment plasma levels after 12 hrs, versus 48 hrs following the administration of glycosylated rhGM-CSF. After intravascular administration, clearance of rhGM-CSF was significantly decreased by the presence of carbohydrates. Non-significant differences in the terminal phase of the biphasic kinetics were found, but the distribution phase was significantly longer for the glycosylated form