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Pharmacokinetic analysis identifies a factor VIII immunogenicity threshold after AAV gene therapy in hemophilia A mice

Advances in the development of novel treatment options for hemophilia A are prevalent. However, the anti–factor VIII (FVIII) neutralizing antibody (inhibitor) response to existing FVIII products remains a major treatment challenge. Although some novel products are designed to function in the presenc...

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Published in:	Blood advances 2022-04, Vol.6 (8), p.2628-2645
Main Authors:	Lundgren, Taran S., Denning, Gabriela, Stowell, Sean R., Spencer, H. Trent, Doering, Christopher B.
Format:	Article
Language:	English
Subjects:	Animals Factor VIII - genetics Factor VIII - therapeutic use Gene Therapy Genetic Therapy Hemophilia A - genetics Hemophilia A - therapy Hemostatics Mice Transgenes
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creator	Lundgren, Taran S. Denning, Gabriela Stowell, Sean R. Spencer, H. Trent Doering, Christopher B.
description	Advances in the development of novel treatment options for hemophilia A are prevalent. However, the anti–factor VIII (FVIII) neutralizing antibody (inhibitor) response to existing FVIII products remains a major treatment challenge. Although some novel products are designed to function in the presence of inhibitors, they do not specific address the immunogenicity risk or mechanistic causes of inhibitor development, which remain unclear. Furthermore, most preclinical studies supporting clinical gene therapy programs have reported immunogenicity signals in animal models, especially at higher vector doses and sometimes using multiple vector designs. In these settings, immunogenicity risk factor determination, comparative immunogenicity of competing vector designs, and the potential for obtaining meaningful prognostic data remain relatively unexplored. Additionally, there remains the opportunity to investigate clinical gene therapy as an alternative to standard immune tolerance induction therapy. The current study was designed to address these issues through longitudinal dose-response evaluation of 4 adeno-associated viral (AAV) vector candidates encoding 2 different FVIII transgenes in a murine model of hemophilia A. Plasma FVIII activity and anti-FVIII antibody data were used to generate a pharmacokinetic model that (1) identifies initial AAV-FVIII product expression kinetics as the dominant risk factor for inhibitor development, (2) predicts a therapeutic window where immune tolerance is achieved, and (3) demonstrates evidence of gene therapy–based immune tolerance induction. Although there are known limitations to the predictive value of preclinical immunogenicity testing, these studies can uncover or support the development of design principles that can guide the development of safe and effective genetic medicines. •Initial FVIII exposure rate is the strongest predictor of immunogenicity after AAV-FVIII gene therapy in hemophilia A mice.•Slower initial FVIII exposure rates evolving to steady-state FVIII levels in the normal or higher range support immune tolerance. [Display omitted]
doi_str_mv	10.1182/bloodadvances.2021006359
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In these settings, immunogenicity risk factor determination, comparative immunogenicity of competing vector designs, and the potential for obtaining meaningful prognostic data remain relatively unexplored. Additionally, there remains the opportunity to investigate clinical gene therapy as an alternative to standard immune tolerance induction therapy. The current study was designed to address these issues through longitudinal dose-response evaluation of 4 adeno-associated viral (AAV) vector candidates encoding 2 different FVIII transgenes in a murine model of hemophilia A. Plasma FVIII activity and anti-FVIII antibody data were used to generate a pharmacokinetic model that (1) identifies initial AAV-FVIII product expression kinetics as the dominant risk factor for inhibitor development, (2) predicts a therapeutic window where immune tolerance is achieved, and (3) demonstrates evidence of gene therapy–based immune tolerance induction. Although there are known limitations to the predictive value of preclinical immunogenicity testing, these studies can uncover or support the development of design principles that can guide the development of safe and effective genetic medicines. •Initial FVIII exposure rate is the strongest predictor of immunogenicity after AAV-FVIII gene therapy in hemophilia A mice.•Slower initial FVIII exposure rates evolving to steady-state FVIII levels in the normal or higher range support immune tolerance. 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Trent</creatorcontrib><creatorcontrib>Doering, Christopher B.</creatorcontrib><title>Pharmacokinetic analysis identifies a factor VIII immunogenicity threshold after AAV gene therapy in hemophilia A mice</title><title>Blood advances</title><addtitle>Blood Adv</addtitle><description>Advances in the development of novel treatment options for hemophilia A are prevalent. However, the anti–factor VIII (FVIII) neutralizing antibody (inhibitor) response to existing FVIII products remains a major treatment challenge. Although some novel products are designed to function in the presence of inhibitors, they do not specific address the immunogenicity risk or mechanistic causes of inhibitor development, which remain unclear. Furthermore, most preclinical studies supporting clinical gene therapy programs have reported immunogenicity signals in animal models, especially at higher vector doses and sometimes using multiple vector designs. In these settings, immunogenicity risk factor determination, comparative immunogenicity of competing vector designs, and the potential for obtaining meaningful prognostic data remain relatively unexplored. Additionally, there remains the opportunity to investigate clinical gene therapy as an alternative to standard immune tolerance induction therapy. The current study was designed to address these issues through longitudinal dose-response evaluation of 4 adeno-associated viral (AAV) vector candidates encoding 2 different FVIII transgenes in a murine model of hemophilia A. Plasma FVIII activity and anti-FVIII antibody data were used to generate a pharmacokinetic model that (1) identifies initial AAV-FVIII product expression kinetics as the dominant risk factor for inhibitor development, (2) predicts a therapeutic window where immune tolerance is achieved, and (3) demonstrates evidence of gene therapy–based immune tolerance induction. Although there are known limitations to the predictive value of preclinical immunogenicity testing, these studies can uncover or support the development of design principles that can guide the development of safe and effective genetic medicines. •Initial FVIII exposure rate is the strongest predictor of immunogenicity after AAV-FVIII gene therapy in hemophilia A mice.•Slower initial FVIII exposure rates evolving to steady-state FVIII levels in the normal or higher range support immune tolerance. 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Plasma FVIII activity and anti-FVIII antibody data were used to generate a pharmacokinetic model that (1) identifies initial AAV-FVIII product expression kinetics as the dominant risk factor for inhibitor development, (2) predicts a therapeutic window where immune tolerance is achieved, and (3) demonstrates evidence of gene therapy–based immune tolerance induction. Although there are known limitations to the predictive value of preclinical immunogenicity testing, these studies can uncover or support the development of design principles that can guide the development of safe and effective genetic medicines. •Initial FVIII exposure rate is the strongest predictor of immunogenicity after AAV-FVIII gene therapy in hemophilia A mice.•Slower initial FVIII exposure rates evolving to steady-state FVIII levels in the normal or higher range support immune tolerance. 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subjects	Animals Factor VIII - genetics Factor VIII - therapeutic use Gene Therapy Genetic Therapy Hemophilia A - genetics Hemophilia A - therapy Hemostatics Mice Transgenes
title	Pharmacokinetic analysis identifies a factor VIII immunogenicity threshold after AAV gene therapy in hemophilia A mice
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