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8 results on '"Sauna A"'

1. Structural, functional, and immunogenicity implications of F9 gene recoding

Author

Katneni, Upendra K., Alexaki, Aikaterini, Hunt, Ryan C., Hamasaki-Katagiri, Nobuko, Hettiarachchi, Gaya K., Kames, Jacob M., McGill, Joseph R., Holcomb, David D., Athey, John C., Lin, Brian, Parunov, Leonid A., Kafri, Tal, Lu, Qi, Peters, Robert, Ovanesov, Mikhail V., Freedberg, Darón I., Bar, Haim, Komar, Anton A., Sauna, Zuben E., and Kimchi-Sarfaty, Chava

Published
2022
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3. Mitigation of T-cell dependent immunogenicity by reengineering factor VIIa analogue

Author

Wojciech Jankowski, Joseph McGill, H.A.Daniel Lagassé, Stepan Surov, Gary Bembridge, Campbell Bunce, Edward Cloake, Mark H. Fogg, Katarzyna I. Jankowska, Abdul Khan, Joseph Marcotrigiano, Mikhail V. Ovanesov, and Zuben E. Sauna

Subjects
Specialties of internal medicine, RC581-951
Abstract

Abstract: Vatreptacog alfa (VA), a recombinant activated human factor VII (rFVIIa) variant with 3 amino acid substitutions, was developed to provide increased procoagulant activity in hemophilia patients with inhibitors to factor VIII or factor IX. In phase 3 clinical trials, changes introduced during the bioengineering of VA resulted in the development of undesired anti-drug antibodies in some patients, leading to the termination of a potentially promising therapeutic protein product. Here, we use preclinical biomarkers associated with clinical immunogenicity to validate our deimmunization strategy applied to this bioengineered rFVIIa analog. The reengineered rFVIIa analog variants retained increased intrinsic thrombin generation activity but did not elicit T-cell responses in peripheral blood mononuclear cells isolated from 50 HLA typed subjects representing the human population. Our algorithm, rational immunogenicity determination, offers a broadly applicable deimmunizing strategy for bioengineered proteins.

Published
2019
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4. Structural, functional, and immunogenicity implications of F9 gene recoding

Author

Upendra K. Katneni, Aikaterini Alexaki, Ryan C. Hunt, Nobuko Hamasaki-Katagiri, Gaya K. Hettiarachchi, Jacob M. Kames, Joseph R. McGill, David D. Holcomb, John C. Athey, Brian Lin, Leonid A. Parunov, Tal Kafri, Qi Lu, Robert Peters, Mikhail V. Ovanesov, Darón I. Freedberg, Haim Bar, Anton A. Komar, Zuben E. Sauna, and Chava Kimchi-Sarfaty

Subjects
Factor IX, Humans, Hematology, Codon, Hemophilia B, Recombinant Proteins, Silent Mutation
Abstract

Hemophilia B is a blood clotting disorder caused by deficient activity of coagulation factor IX (FIX). Multiple recombinant FIX proteins are currently approved to treat hemophilia B, and several gene therapy products are currently being developed. Codon optimization is a frequently used technique in the pharmaceutical industry to improve recombinant protein expression by recoding a coding sequence using multiple synonymous codon substitutions. The underlying assumption of this gene recoding is that synonymous substitutions do not alter protein characteristics because the primary sequence of the protein remains unchanged. However, a critical body of evidence shows that synonymous variants can affect cotranslational folding and protein function. Gene recoding could potentially alter the structure, function, and in vivo immunogenicity of recoded therapeutic proteins. Here, we evaluated multiple recoded variants of F9 designed to further explore the effects of codon usage bias on protein properties. The detailed evaluation of these constructs showed altered conformations, and assessment of translation kinetics by ribosome profiling revealed differences in local translation kinetics. Assessment of wild-type and recoded constructs using a major histocompatibility complex (MHC)-associated peptide proteomics assay showed distinct presentation of FIX-derived peptides bound to MHC class II molecules, suggesting that despite identical amino acid sequence, recoded proteins could exhibit different immunogenicity risks. Posttranslational modification analysis indicated that overexpression from gene recoding results in suboptimal posttranslational processing. Overall, our results highlight potential functional and immunogenicity concerns associated with gene-recoded F9 products. These findings have general applicability and implications for other gene-recoded recombinant proteins.

Published
2022

5. Structural, functional, and immunogenicity implications of F9gene recoding

Author

Katneni, Upendra K., Alexaki, Aikaterini, Hunt, Ryan C., Hamasaki-Katagiri, Nobuko, Hettiarachchi, Gaya K., Kames, Jacob M., McGill, Joseph R., Holcomb, David D., Athey, John C., Lin, Brian, Parunov, Leonid A., Kafri, Tal, Lu, Qi, Peters, Robert, Ovanesov, Mikhail V., Freedberg, Darón I., Bar, Haim, Komar, Anton A., Sauna, Zuben E., and Kimchi-Sarfaty, Chava

Abstract

Hemophilia B is a blood clotting disorder caused by deficient activity of coagulation factor IX (FIX). Multiple recombinant FIX proteins are currently approved to treat hemophilia B, and several gene therapy products are currently being developed. Codon optimization is a frequently used technique in the pharmaceutical industry to improve recombinant protein expression by recoding a coding sequence using multiple synonymous codon substitutions. The underlying assumption of this gene recoding is that synonymous substitutions do not alter protein characteristics because the primary sequence of the protein remains unchanged. However, a critical body of evidence shows that synonymous variants can affect cotranslational folding and protein function. Gene recoding could potentially alter the structure, function, and in vivo immunogenicity of recoded therapeutic proteins. Here, we evaluated multiple recoded variants of F9designed to further explore the effects of codon usage bias on protein properties. The detailed evaluation of these constructs showed altered conformations, and assessment of translation kinetics by ribosome profiling revealed differences in local translation kinetics. Assessment of wild-type and recoded constructs using a major histocompatibility complex (MHC)-associated peptide proteomics assay showed distinct presentation of FIX-derived peptides bound to MHC class II molecules, suggesting that despite identical amino acid sequence, recoded proteins could exhibit different immunogenicity risks. Posttranslational modification analysis indicated that overexpression from gene recoding results in suboptimal posttranslational processing. Overall, our results highlight potential functional and immunogenicity concerns associated with gene-recoded F9products. These findings have general applicability and implications for other gene-recoded recombinant proteins.

Published
2022
Full Text
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6. Mitigation of T-cell dependent immunogenicity by reengineering factor VIIa analogue

Author

Gary Bembridge, Stepan S Surov, H.A. Daniel Lagassé, Mikhail V Ovanesov, Zuben E. Sauna, Wojciech Jankowski, Mark H. Fogg, Edward A. Cloake, Joseph Marcotrigiano, Joseph R. McGill, Campbell Bunce, Katarzyna I. Jankowska, and Abdul Ghafoor Khan

Subjects
0301 basic medicine, T-Lymphocytes, Population, Factor VIIa, 030204 cardiovascular system & hematology, Pharmacology, Hemophilia A, Protein Engineering, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Hemophilias, Medicine, Humans, Immunogenetic Phenomena, education, Deimmunization, Cells, Cultured, Factor IX, Blood coagulation test, education.field_of_study, Factor VII, business.industry, Immunogenicity, Thrombin, Hematology, Turoctocog alfa, Gene Therapy, Recombinant Proteins, 030104 developmental biology, chemistry, Blood Coagulation Tests, business, medicine.drug
Abstract

Vatreptacog alfa (VA), a recombinant activated human factor VII (rFVIIa) variant with 3 amino acid substitutions, was developed to provide increased procoagulant activity in hemophilia patients with inhibitors to factor VIII or factor IX. In phase 3 clinical trials, changes introduced during the bioengineering of VA resulted in the development of undesired anti-drug antibodies in some patients, leading to the termination of a potentially promising therapeutic protein product. Here, we use preclinical biomarkers associated with clinical immunogenicity to validate our deimmunization strategy applied to this bioengineered rFVIIa analog. The reengineered rFVIIa analog variants retained increased intrinsic thrombin generation activity but did not elicit T-cell responses in peripheral blood mononuclear cells isolated from 50 HLA typed subjects representing the human population. Our algorithm, rational immunogenicity determination, offers a broadly applicable deimmunizing strategy for bioengineered proteins.

Published
2019

7. Peptides identified on monocyte-derived dendritic cells: a marker for clinical immunogenicity to FVIII products

Author

Yara A. Park, Zuben E. Sauna, Tom E. Howard, Eugene Maraskovsky, Nigel S. Key, Marco Hofmann, Joseph R. McGill, Vincent P. Diego, Roberta Kellerman, Bernadette W. Luu, and Wojciech Jankowski

Subjects
0301 basic medicine, HLA-DP Antigens, Peptide, 030204 cardiovascular system & hematology, Major histocompatibility complex, Hemophilia A, Peptide Mapping, Epitope, Thrombosis and Hemostasis, 03 medical and health sciences, Epitopes, 0302 clinical medicine, Immune system, Von Willebrand factor, hemic and lymphatic diseases, HLA-DQ Antigens, von Willebrand Factor, Medicine, Humans, chemistry.chemical_classification, MHC class II, Factor VIII, biology, business.industry, Immunogenicity, Hematology, Dendritic Cells, HLA-DR Antigens, 030104 developmental biology, Drug development, chemistry, Immunology, biology.protein, Leukocytes, Mononuclear, business, Peptides
Abstract

The immunogenicity of protein therapeutics is an important safety and efficacy concern during drug development and regulation. Strategies to identify individuals and subpopulations at risk for an undesirable immune response represent an important unmet need. The major histocompatibility complex (MHC)–associated peptide proteomics (MAPPs) assay directly identifies the presence of peptides derived from a specific protein therapeutic on a donor’s MHC class II (MHC-II) proteins. We applied this technique to address several questions related to the use of factor VIII (FVIII) replacement therapy in the treatment of hemophilia A (HA). Although >12 FVIII therapeutics are marketed, most fall into 3 categories: (i) human plasma-derived FVIII (pdFVIII), (ii) full-length (FL)–recombinant FVIII (rFVIII; FL-rFVIII), and (iii) B-domain–deleted rFVIII. Here, we investigated whether there are differences between the FVIII peptides found on the MHC-II proteins of the same individual when incubated with these 3 classes. Based on several observational studies and a prospective, randomized, clinical trial showing that the originally approved rFVIII products may be more immunogenic than the pdFVIII products containing von Willebrand factor (VWF) in molar excess, it has been hypothesized that the pdFVIII molecules yield/present fewer peptides (ie, potential T-cell epitopes). We have experimentally tested this hypothesis and found that dendritic cells from HA patients and healthy donors present fewer FVIII peptides when administered pdFVIII vs FL-rFVIII, despite both containing the same molar VWF excess. Our results support the hypothesis that synthesis of pdFVIII under physiological conditions could result in reduced heterogeneity and/or subtle differences in structure/conformation which, in turn, may result in reduced FVIII proteolytic processing relative to FL-rFVIII.

Published
2018

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