Point Mutation Approach to Reduce Antigenicity of Interferon Beta

Interferon beta (IFNβ) is naturally occurring cytokine made and secreted by immune cells in response to stimuli. Non-glycosylated interferon beta Ser 17 mutein (IFNβ-Ser17) is widely used for treatment of active relapsing multiple sclerosis. Despite all efforts to humanize this protein, it is still...

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Bibliographic Details
Published in:International journal of peptide research and therapeutics 2020-09, Vol.26 (3), p.1353-1361
Main Authors: Haji Abdolvahab, Mohadeseh, Venselaar, Hanka, Fazeli, Ahmad, Arab, S. Shahriar, Behmanesh, Mehrdad
Format: Article
Language:English
Subjects:
Animal Anatomy
Antibodies
Antigenicity
Antiviral activity
Biochemistry
Biomedical and Life Sciences
C-Terminus
Chemiluminescence
Computer applications
Epitopes
Histology
Immunogenicity
Interferon
Life Sciences
Molecular Medicine
Morphology
Multiple sclerosis
Mutation
N-Terminus
Peptides
Pharmaceutical Sciences/Technology
Pharmacology/Toxicology
Point mutation
Polymer Sciences
Synthetic peptides
Transgenic mice
β-Interferon
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Summary:Interferon beta (IFNβ) is naturally occurring cytokine made and secreted by immune cells in response to stimuli. Non-glycosylated interferon beta Ser 17 mutein (IFNβ-Ser17) is widely used for treatment of active relapsing multiple sclerosis. Despite all efforts to humanize this protein, it is still immunogenic by increasing of anti-IFNβ antibodies in patients. In order to decrease its antigenicity, identification and modification of epitopes is an effective step. We used a peptide microarray to detect linear epitopes by screening a synthetic peptide library. The interaction between synthetic peptides and anti-IFNβ antibodies presented in enriched plasma of transgenic and non-transgenic mice, were detected using chemiluminescence. With this technique, three 10-mer peptides were identified as linear epitopes. Computational algorithms were used to select residues suitable for point mutations in each epitope. These three 10-mer epitopes were mutated with the aim to reduce antigenicity of IFNβ. Three variants of IFNβ each with one mutated epitope were produced. The results showed no binding affinity of the mutated epitopes to anti-IFNβ antibodies compared with native epitopes. Biological activities of these epitope variants were measured; equal antiviral activity of the C-terminus mutated and the near N-terminus mutated were evaluated compare to the standard. Our results showed that the antigenicity of IFNβ epitope variants were reduced in vitro.
ISSN:1573-3149
1573-3904
DOI:10.1007/s10989-019-09938-9