Your search keyword '"Allen JWL"' showing total 2 results

1. Marginal zone B cells mediate a CD4 T-cell-dependent extrafollicular antibody response following RBC transfusion in mice.

Author

Zerra PE, Patel SR, Jajosky RP, Arthur CM, McCoy JW, Allen JWL, Chonat S, Fasano RM, Roback JD, Josephson CD, Hendrickson JE, and Stowell SR

Subjects

Animals, Duffy Blood-Group System genetics, Female, Humans, Immunoglobulin G genetics, Immunoglobulin G immunology, Immunoglobulin M genetics, Immunoglobulin M immunology, Isoantibodies genetics, Isoantigens genetics, Mice, Mice, Knockout, Receptors, Cell Surface genetics, B-Lymphocytes immunology, Duffy Blood-Group System immunology, Erythrocyte Transfusion, Germinal Center immunology, Isoantibodies immunology, Isoantigens immunology, Receptors, Cell Surface immunology

Abstract

Red blood cell (RBC) transfusions can result in alloimmunization toward RBC alloantigens that can increase the probability of complications following subsequent transfusion. An improved understanding of the immune mechanisms that underlie RBC alloimmunization is critical if future strategies capable of preventing or even reducing this process are to be realized. Using the HOD (hen egg lysozyme [HEL] and ovalbumin [OVA] fused with the human RBC antigen Duffy) model system, we aimed to identify initiating immune factors that may govern early anti-HOD alloantibody formation. Our findings demonstrate that HOD RBCs continuously localize to the marginal sinus following transfusion, where they colocalize with marginal zone (MZ) B cells. Depletion of MZ B cells inhibited immunoglobulin M (IgM) and IgG anti-HOD antibody formation, whereas CD4 T-cell depletion only prevented IgG anti-HOD antibody development. HOD-specific CD4 T cells displayed similar proliferation and activation following transfusion of HOD RBCs into wild-type or MZ B-cell-deficient recipients, suggesting that IgG formation is not dependent on MZ B-cell-mediated CD4 T-cell activation. Moreover, depletion of follicular B cells failed to substantially impact the anti-HOD antibody response, and no increase in antigen-specific germinal center B cells was detected following HOD RBC transfusion, suggesting that antibody formation is not dependent on the splenic follicle. Despite this, anti-HOD antibodies persisted for several months following HOD RBC transfusion. Overall, these data suggest that MZ B cells can initiate and then contribute to RBC alloantibody formation, highlighting a unique immune pathway that can be engaged following RBC transfusion., (© 2021 by The American Society of Hematology.)

Published

2021

2. Fc Gamma Receptors and Complement Component 3 Facilitate Anti-fVIII Antibody Formation.

Author

Zerra PE, Arthur CM, Chonat S, Maier CL, Mener A, Shin S, Allen JWL, Baldwin WH, Cox C, Verkerke H, Jajosky RP, Tormey CA, Meeks SL, and Stowell SR

Subjects

Animals, Antibody Formation, Complement C3 deficiency, Complement C3 genetics, Disease Models, Animal, Factor VIII administration & dosage, Female, Hemophilia A blood, Hemophilia A drug therapy, Hemophilia A genetics, Isoantigens administration & dosage, Mice, Inbred C57BL, Mice, Knockout, Receptors, IgG deficiency, Receptors, IgG genetics, Complement C3 metabolism, Factor VIII immunology, Hemophilia A immunology, Isoantibodies blood, Isoantigens immunology, Receptors, IgG metabolism

Abstract

Anti-factor VIII (fVIII) alloantibodies, which can develop in patients with hemophilia A, limit the therapeutic options and increase morbidity and mortality of these patients. However, the factors that influence anti-fVIII antibody development remain incompletely understood. Recent studies suggest that Fc gamma receptors (FcγRs) may facilitate recognition and uptake of fVIII by recently developed or pre-existing naturally occurring anti-fVIII antibodies, providing a mechanism whereby the immune system may recognize fVIII following infusion. However, the role of FcγRs in anti-fVIII antibody formation remains unknown. In order to define the influence of FcγRs on the development of anti-fVIII antibodies, fVIII was injected into WT or FcγR knockout recipients, followed by evaluation of anti-fVIII antibodies. Anti-fVIII antibodies were readily observed following fVIII injection into FcγR knockouts, with similar anti-fVIII antibody levels occurring in FcγR knockouts as detected in WT mice injected in parallel. As antibodies can also fix complement, providing a potential mechanism whereby anti-fVIII antibodies may influence anti-fVIII antibody formation independent of FcγRs, fVIII was also injected into complement component 3 (C3) knockout recipients in parallel. Similar to FcγR knockouts, C3 knockout recipients developed a robust response to fVIII, which was likewise similar to that observed in WT recipients. As FcγRs or C3 may compensate for each other in recipients only deficient in FcγRs or C3 alone, we generated mice deficient in both FcγRs and C3 to test for potential antibody effector redundancy in anti-fVIII antibody formation. Infusion of fVIII into FcγRs and C3 (FcγR × C3) double knockouts likewise induced anti-fVIII antibodies. However, unlike individual knockouts, anti-fVIII antibodies in FcγRs × C3 knockouts were initially lower than WT recipients, although anti-fVIII antibodies increased to WT levels following additional fVIII exposure. In contrast, infusion of RBCs expressing distinct alloantigens into FcγRs, C3 or FcγR × C3 knockout recipients either failed to change anti-RBC levels when compared to WT recipients or actually increased antibody responses, depending on the target antigen. Taken together, these results suggest FcγRs and C3 can differentially impact antibody formation following exposure to distinct alloantigens and that FcγRs and C3 work in concert to facilitate early anti-fVIII antibody formation., (Copyright © 2020 Zerra, Arthur, Chonat, Maier, Mener, Shin, Allen, Baldwin, Cox, Verkerke, Jajosky, Tormey, Meeks and Stowell.)

Published

2020