Natalia Ceaglio

Highly glycosylated human alpha interferon: An insight into a new therapeutic candidate.

The type I human interferon alpha (hIFN-alpha) family consists of small proteins that exert a multiplicity of biological actions including antiviral, antiproliferative and immunomodulatory effects. However, though administration of recombinant hIFN-alpha2b is the current treatment for chronic hepatitis B and C and for some types of cancers, therapy outcomes have not been completely satisfactory. The short serum half-life and rapid clearance of the cytokine accounts for its low in vivo biological activity. Here we describe and characterize a long-acting rhIFN-alpha2b mutein, 4N-IFN, which has been created by introducing four N-glycosylation sites via site-directed mutagenesis. The hyperglycosylated protein was found to have a 25-fold longer plasma half-life than the non-glycosylated rhIFN-alpha2b, even greater than the commercial pegylated derivative Intron-A PEG. In addition, glycosylation increased the in vitro stability of the mutein against serum protease inactivation. Interestingly, despite its lower in vitro activity, 4N-IFN showed a markedly enhanced in vivo antitumor activity in human prostate carcinoma implanted in nude mice. MALDI-TOF MS and HPAEC-PAD carbohydrate analyses revealed the presence of high amounts of tetrasialylated (40%) and trisialylated (28%) N-glycan structures, which are consequently responsible for the improved characteristics of the cytokine, making 4N-IFN a new therapeutic candidate for viral and malignant diseases.

Influence of carbohydrates on the stability and structure of a hyperglycosylated human interferon alpha mutein

Protein physical and chemical instability is one of the major challenges in the development of biopharmaceuticals during every step of the process, ranging from production to final delivery. This is particularly applicable to human recombinant interferon alpha-2b (rhIFN-alpha2b), a pleiotropic cytokine currently used worldwide for the treatment of various cancer and chronic viral diseases, which presents a poor stability in solution. In previous studies, we have demonstrated that the introduction of four N-glycosylation sites in order to construct a heavily glycosylated IFN variant (4N-IFN) resulted in a markedly prolonged plasma half-life which was reflected in an enhanced therapeutic activity in mice in comparison with the commercial non-glycosylated rhIFN-alpha2b (NG-IFN). Herein, we evaluated the influence of glycosylation on the in vitro stability of 4N-IFN towards different environmental conditions. Interestingly, the hyperglycosylated cytokine showed enhanced stability against thermal stress, acid pH and repetitive freeze-thawing cycles in comparison with NG-IFN. Besides, microcalorimetric analysis indicated a much higher melting temperature of 4N-IFN, also demonstrating a higher solubility of this variant as denoted by the absence of precipitation at the end of the experiment, in contrast with the NG-IFN behaviour. Furthermore, far-UV circular dichroism (CD) spectrum of 4N-IFN was virtually superimposed with that of NG-IFN, indicating that the IFN structure was not altered by the addition of carbohydrate moieties. The same conclusion could be inferred from limited proteolysis studies. Our results suggest that glycoengineering could be a useful strategy for protecting rhIFN-alpha2b from inactivation by various external factors and for overcoming aggregation problems during the production process and storage.

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, Parkinsons Disease, among others). Nonetheless, EPOs 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.

Improvement of in vitro stability and pharmacokinetics of hIFN-α by fusing the carboxyl-terminal peptide of hCG β-subunit

Improving in vivo half-life and in vitro stability of protein-based therapeutics is a current challenge for the biopharmaceutical industry. In particular, recombinant human interferon alpha-2b (rhIFN-α2b), which belongs to a group of cytokines extensively used for the treatment of viral diseases and cancers, shows a poor stability in solution and an extremely short plasma half-life which determines a strict therapeutic regimen comprising high and repeated doses. In this work, we have used a strategy based on the fusion of the carboxyl-terminal peptide (CTP) of human chorionic gonadotropin (hCG) β-subunit, bearing four O-linked oligosaccharide recognition sites, to each or both N- and C-terminal ends of rhIFN-α2b. Molecules containing from 5 (CTP-IFN and IFN-CTP) to 9 (CTP-IFN-CTP) O-glycosylation sites were efficiently expressed and secreted to CHO cells supernatants, and exhibited antiviral and antiproliferative bioactivities in vitro. Significant improvements in pharmacokinetics in rats were achieved through this approach, since the doubly CTP-modified IFN variant showed a 10-fold longer elimination half-life and a 19-fold decreased plasma apparent clearance compared to the wild-type cytokine. Moreover, CTP-IFN-CTP demonstrated a significant increase in in vitro thermal resistance and a higher stability against plasma protease inactivation, both features attributed to the stabilizing effects of the O-glycans provided by the CTP moiety. These results constitute the first report that postulates CTP as a tag for improving both the in vitro and in vivo stability of rhIFN-α2b which, in turn, would positively influence its in vivo bioactivity.

High performance collection of cerebrospinal fluid in rats: Evaluation of erythropoietin penetration after osmotic opening of the blood–brain barrier

An important issue to be considered when studying a new drug for treatment of central nervous system (CNS) diseases is its ability to cross the blood-brain barrier (BBB) and distribute throughout the brain. As cerebrospinal fluid (CSF) has demonstrated to be an invaluable reservoir to study CNS availability of therapeutic proteins, we have developed an improved method for CSF sampling from the cisterna magna of rats. The technique enables the simple and rapid collection of adequate quantities (50-75 μl) of blood-free CSF, rendering a high percentage of animal survival (99%) without clinic or neurological consequences. Its success in avoiding blood contamination of CSF lays in the use of a mixture of lidocaine/ephinephrine topically injected in the rats suboccipital area and neck. Another relevant feature of the methodology is its low cost, since the puncture device can be easily assembled with cheap and available materials and, more importantly, neither expensive stereotaxic equipment nor frame is required. The present method is demonstrated by studying the CSF pharmacokinetics of recombinant human erythropoietin (rhEPO), a well-studied therapeutic candidate for neurological diseases. Moreover, we applied this technique to evaluate a strategy of osmotic disruption of the BBB to achieve a faster delivery of rhEPO into the CNS.

Neuroprotective activity of a new erythropoietin formulation with increased penetration in the central nervous system

BackgroundApart from its hematopoietic effect, erythropoietin(EPO) is a molecule with high neuroprotective potential.However, its prolonged application may cause seriousadverse effects due to the erythropoiesis stimulation.Therefore, an EPO derivative with neuroprotective prop-erties but low hematopoietic activity, designated as neu-ropoietin (rhNEPO), was developed in our lab using analternative purification process of the recombinanthuman erythropoietic counterpart (rhEPO) produced inCHO cells [1]. The in vitro cytoprotective activity ofrhNEPO on neural phenotype cells and its brain uptakefrom blood are herein analyzed.ResultsIn vitro citoprotective activity of rhNEPO was analyzedon rat pheochromocytoma cells (PC-12) differentiated toneural phenotype with neural growth factor (NGF).Apoptosis was triggered by NGF and serum withdrawalfrom cell cultures. Thus, nuclear DNA fragmentationwas analyzed by colorimetric TUNEL detection. One-way analysis of variance was carried out followed byDunnett´s multiple comparison test. Probabilities lowerthan 0.05 were considered significant (p 0.05), confirming their prop-erties to protect PC-12 cells from apoptosis. Therefore,this novel combination of erythropoietin glycoforms(rhNEPO) with lower sialic acid content and antennaritythan rhEPO [1] preserved its binding receptor capacityexerting an in vitro neuroprotective activity even betterthan the mentioned counterpart. Also, rhAEPO showedan in vitro activity that is similar to that of rhNEPO,having both derivatives the lowest content of carbohy-drates. It is well known that the affinity of EPO analo-gues for EPO receptor is inversely related to thesialylation of their attached carbohydrate [2] and thatremoval of sialic acid turns it into a molecule with avery short half-life with almost no erythropoietic activ-ity. This is the case of rhAEPO that explains its rapidhepatic clearance from blood [3]. For that reason,rhNEPO emerges as a neuroprotective candidate dis-playing higher in vitro activity than rhEPO.Taking into account the cytoprotective activity ofrhNEPO on neural phenotype cells, cerebrospinal fluid(CSF) and blood pharmacokinetics of rhEPO andrhNEPO were evaluated in rats following intravenousadministration of a single dose of each protein, aimingto evaluate their CSF uptake from plasma.The distribution and the elimination half-lives ofrhNEPO in blood were significantly shorter than thecorresponding ones for rhEPO. Differences in the sialic

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

Graphical abstract Figure. No caption available. HighlightsHyperglycosylated human IFN‐&agr;2 was produced in CHO and HEK cells.CHO‐derived IFN showed highly sialylated and branched glycans.HEK‐derived IFN displayed smaller and truncated glycans compared to CHO‐derived one.Differences in the glycosylation pattern had not a considerable impact on the elimination half‐life.Hyperglycosylated IFN produced in HEK was more efficient as an antiproliferative agent in vitro.IFN4NHEK showed a higher in vivo antitumor activity in animal models. Abstract 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‐&agr;2b 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.

Novel reactive PEG for amino group conjugation

Activated mPEG carbonates are important reagents that have been widely used for the PEGylation of several peptides and proteins by means of stable urethane linkages. In fact, mPEG-N-hydroxysuccinimidyl carbonate and mPEG-p-nitrophenyl carbonate are among the most used reagents in PEGylation technology. However, the synthesis and storage of these reagents are not always easy to resolve. With the aim of surpassing some of the drawbacks associated with the use of activated mPEG-carbonates we have prepared and evaluated a new mPEG-carbonylimidazolium iodide, which can be used for the conjugation of the NH2 group by means of urethane linkages, as an interesting alternative to the known reagents. It is noteworthy that the novel reagent is prepared by a simple two-step procedure under mild experimental conditions. Moreover, we performed a detailed study of the conjugation reaction of interferon-α2b with the carbonylimidazolium derivative, and evaluated the conjugate in in vitro and in vivo studies.

Novel Poly(Diol Sebacate)s as Additives to Modify Paclitaxel Release From Poly(Lactic-co-Glycolic Acid) Thin Films

Paclitaxel (PTX) incorporation in poly(lactic-co-glycolic acid) (PLGA) matrices produce films with high tensile rigidity and slow release that fail to deliver the required release rate for most biomedical applications such as in drug eluting stents and cancer treatments. To modify and improve this behavior, a set of poly(diol sebacate)s were synthesized and fully characterized as possible additives. The tensile properties of PLGA blends were evaluated as these materials could be used as coatings in drug eluting stent applications. A significant improvement in mechanical flexibility was observed with 20% additive content, as it reduced the Youngs modulus value and increased the maximum deformation at break. PTX release was studied and correlated with the release of additive from PLGA films. An increase in the initial burst release phase was observed on all blends when compared to the control films of PLGA. Modulation of PTX release was achieved by altering the hydrophilicity degree of the additive or its percentage content on the blend. This supports the possibility that PTX was partitioned into the additive phase. Cytotoxicity analyses of novel additives were performed on mouse embryonic fibroblasts NIH/3T3.

Differences in the production of hyperglycosylated IFN alpha in CHO and HEK 293 cells

Background IFN alpha is an important cytokine of the immune system. It has the ability to interfere with virus replication exerting antiviral activity. Moreover, it displays antiproliferative activity and can profoundly modulate the immune response. IFN4N (or hyperglycosylated IFN alpha) is an IFN-alpha2b mutein developed in our laboratory using glycoengineering strategies. This molecule contains 4 potential N-glycosylation sites together with the natural O-glycosylation site in Thr106 [1]. The resulting Nand O-glycosylated protein shows higher apparent molecular mass and longer plasmatic half-life compared to the nonglycosylated IFN-alpha produced in bacterial systems and used for clinical applications. As a consequence, the correct glycosylation of our modified cytokine is very important for its in vivo activity. For this reason, it is of great relevance the evaluation of different mammalian host cells for its production. While hamster-derived CHO cells are widely used for large scale production of recombinant therapeutic glycoproteins, human HEK cells are a promising system because they are easy to grow and transfect [2]. In this work, we performed a comparison between both production systems in terms of cell growth, culture parameters and specific productivity of hyperglycosylated IFN alpha.