Development of IFNß-1a versions with reduced immunogenicity and full in vitro biological activity for the treatment of multiple sclerosis.

IFNß (recombinant interferon Beta) has been widely used for the treatment of Multiple sclerosis for the last four decades. Despite the human origin of the IFNß sequence, IFNß is immunogenic, and unwanted immune responses in IFNß-treated patients may compromise its efficacy and safety in the clinic. In this study, we applied the DeFT (De-immunization of Functional Therapeutics) approach to producing functional, de-immunized versions of IFNß-1a. Two de-immunized versions of IFNß-1a were produced in CHO cells and designated as IFNß-1a(VAR1) and IFNß-1a(VAR2). First, the secondary and tertiary protein structures were analyzed by circular dichroism spectroscopy. Then, the variants were also tested for functionality. While IFNß-1a(VAR2) showed similar in vitro antiviral activity to the original protein, IFNß-1a(VAR1) exhibited 40% more biological potency. Finally, in vivo assays using HLA-DR transgenic mice revealed that the de-immunized variants showed a markedly reduced immunogenicity when compared to the originator.

Specific sequence mutations in a long-lasting rhIFN-α2b version reduce in vitro and in vivo immunogenicity and increase in vitro protein stability.

For decades, recombinant human interferon alpha (rhIFN-α2b) has been used to treat emerging and chronic viral diseases. However, rhIFN-α2b is immunogenic and has a short in vivo half-life. To solve these limitations, two long-lasting hyperglycosylated proteins with reduced immunogenicity were developed and designated as 4N-IFN(VAR1) and 4N-IFN(VAR3). Here, we continue to study the relevant characteristics of these therapeutic candidates. Thus, we demonstrated that both de-immunized IFN versions elicited significantly lower neutralizing antibody responses than the original molecule in HLA-DR1 transgenic mice, confirming our previous in vitro protein immunogenicity data. Also, we found that these biobetters exhibited remarkable stability when exposed to different physical factors that the protein product may encounter during its production process and storage, such as low pH, thermal stress, and repeated freezing/thawing cycles. Taking into consideration our previous and present results, 4N-IFN(VAR1) and 4N-IFN-4N(VAR3) appear to be valuable candidates for the treatment of human viral diseases.

Development of highly stable and de-immunized versions of recombinant alpha interferon: Promising candidates for the treatment of chronic and emerging viral diseases.

Human interferon alpha (hIFN-α) administration constitutes the current FDA approved therapy for chronic Hepatitis B and C virus infections. Additionally, hIFN-α treatment efficacy was recently demonstrated in patients with COVID-19. Thus, hIFN-α constitutes a therapeutic alternative for those countries where vaccination is inaccessible and for people who did not respond effectively to vaccination. However, hIFN-α2b exhibits a short plasma half-life resulting in the occurrence of severe side effects. To optimize the cytokine's pharmacokinetic profile, we developed a hyperglycosylated IFN, referred to as GMOP-IFN. Given the significant number of reports showing neutralizing antibodies (NAb) formation after hIFN-α administration, here we applied the DeFT (De-immunization of Functional Therapeutics) approach to develop functional, de-immunized versions of GMOP-IFN. Two GMOP-IFN variants exhibited significantly reduced ex vivo immunogenicity and null antiproliferative activity, while preserving antiviral function. The results obtained in this work indicate that the new de-immunized GMOP-IFN variants constitute promising candidates for antiviral therapy.

Development of lentiviral vectors for transient and stable protein overexpression in mammalian cells. A new strategy for recombinant human FVIII (rhFVIII) production.

BACKGROUND: Recombinant protein overexpression in mammalian cells constitutes a real challenge in therapeutic protein production. Following the discovery of intron functionality in gene expression, various expression vectors that include them in their sequences have been developed. In this study, the main goal was to develop new lentiviral vectors (LVs) carrying different promoter and intron-containing 5'UTR (5' untranslated region) combinations and the design of LVs for rhFVIII production in Chinese hamster ovary (CHO) cells. RESULTS: By combining the human cytomegalovirus (CMV) or the elongation factor 1α (EF-1α) promoters along with different 5'UTRs that included leader introns, between 2 and 12-fold increases were reached, when transient and stable expression of the enhanced green fluorescent protein (EGFP) and rhFVIII were analyzed. Also, new LVs provided with promoters and 5'UTRs from high expression genes, according to a gene database, were designed. Three of them were shown to be superior to the EF-1α promoter in three widely used cell lines. CONCLUSION: In the present work, LVs containing different promoters and 5'UTRs were designed. In transient and stable assays some of these constructs have shown higher activity compared with commercial promoters and, therefore, constitute promising candidates for therapeutic protein production.