A major obstacle in treating hemophilia A is that ~25% of patients develop high-titer, neutralizing anti-factor VIII (FVIII) antibodies (inhibitors) following protein replacement therapy. It is also anticipated that this problem will occur following gene therapy in at least a subset of patients. It is particularly challenging to treat hemophilia patients who have developed inhibitory antibodies. Bypassing therapies that are used to treat these patients sometimes have limited efficacy and are very costly. The anti-FVIII inhibitory antibody formation results from a complex multifaceted immune response involving both genetic and environmental risk factors. Several ?danger signals? have been demonstrated to be associated with risks of inhibitor formation. However, the potential triggers to activate anti-FVIII responses are not fully understood. For example, patients with identical mutations in FVIII gene can have differential risks in inhibitor development following protein replacement therapy. Moreover, there were some implications that different FVIII products may exhibit different degrees of inhibitor risks. In recent years, it has been demonstrated that glycans are crucial for the immune system, as some of the most important interactions between the immune system and viruses or bacteria or exogenously added proteins are mediated by protein-glycan interactions. Glycosylation is involved in almost every step of the immune activation pathway. Glycans are a key in the recognition of non-self events and an altered glycome can lead to activation of immune responses. Glycosylation is also involved in the cellular mechanisms that control the threshold of TCR activation, immune cell trafficking, TCR and BCR signaling, antibody function, and more. We hypothesize that the impact of glycans in the induction of immune response or tolerance to FVIII can be twofold: one is that the interaction of glycosylated FVIII antigens and host immune system with specific glycan profiles can be significant in determining the risk of inducing anti-FVIII immune response; and the second is that the recognition of and ensued immune activation by exogenously added protein or gene expression can be altered by different extent or patterns of FVIII glycomes. Therefore, in order to more fully understand the spectrum of potential glycosylation influence on the development of anti-FVIII inhibitor responses, we propose to first look into the influence of host glycan profiles in the development of anti-FVIII response both in humans and mice with different backgrounds. Next we will characterize the immune responses elicited by delivery of FVIII molecules with different extent or patterns of glycosylation and investigate the mechanism of immune activation. From this study, we wish to define specific immunologic trigger by glycosylation and its associated mechanisms, leading to prevention or elimination of FVIII inhibitors.
| Aloor, Arya; Zhang, Junping; Gashash, Ebtesam A et al. (2018) Site-Specific N-Glycosylation on the AAV8 Capsid Protein. Viruses 10: |
| Xiao, Weidong; Gao, Guangping; Ling, Chen et al. (2018) Impact of neutralizing antibodies against AAV is a key consideration in gene transfer to nonhuman primates. Nat Med 24:699 |
| Zhang, Wei; Mao, Jianhua; Shen, Yan et al. (2018) Evaluation of the activity levels of rat FVIII and human FVIII delivered by adeno-associated viral vectors both in vitro and in vivo. Blood Cells Mol Dis 73:47-54 |
| Gashash, Ebtesam A; Aloor, Arya; Li, Dong et al. (2017) An Insight into Glyco-Microheterogeneity of Plasma von Willebrand Factor by Mass Spectrometry. J Proteome Res 16:3348-3362 |
