Abstract
Background: Fetal and neonatal alloimmune thrombocytopenia (FNAIT) is a devastating disorder characterized by an aberrant maternal immune response against paternally inherited polymorphisms on fetal platelet antigens. Affected fetuses can experience severe bleeding (e.g. intracranial hemorrhage; ICH), neurological sequelae and death. The targeted platelet antigens are located predominantly on platelet surface receptor αIIbβ3 integrin. It is estimated that 0.5-1.5/1000 live neonates are born with FNAIT although this incidence may largely underestimate the prevalence of the disease due to miscarriage. We have previously demonstrated that anti-β3 alloantibodies can target not only fetal platelets but also the β3 subunit on endothelial cells leading to ICH and placental vascular pathologies (J Clin Invest. 2015; Nat Commun. 2017). Although the number of polymorphisms in the αIIb subunit is similar to the β3 subunit, reported incidences of anti-β3 mediated FNAIT are far greater. It is currently unknown whether this due to miscarriage in anti-αIIb mediated FNAIT. αIIb was previously considered to be exclusively expressed on platelets, however hematopoietic stem cells (HSCs) and their early progenitors can express αIIbβ3 during embryonic development and αIIb is one of the earliest markers of hematopoietic commitment. Throughout gestation, HSCs migrate from yolk sac to the aorta-gonadal-mesonephros, placenta, fetal liver and finally bone marrow. We hypothesize that miscarriage is prevalent in anti-αIIb mediated FNAIT and that maternal anti-αIIb antibodies may target HSCs resulting in decreased blood cell counts, increased bleeding and fetal death.
Methods: We established an animal model of anti-αIIb mediated FNAIT by immunizing αIIb-/- mice with 108 wild-type (WT, αIIb+/+) platelets. Immunized αIIb-/- mice were then bred with WT males. We used non-immunized (naïve) αIIb-/- x WT breeding pairs as a control. Sera of immunized and naïve mice were collected prior to breeding and ultrasound was used to detect fetal death. Mice were sacrificed at E14.5 and fetuses, placentas and fetal livers were weighed. Cell suspensions were prepared from these tissues as well as fetal blood and analyzed with flow cytometry. Fluorescent markers were used to identify HSCs (CD34+/CD117+/Lin- or CD34+/CD45+) and blood cell counts for T cells (CD3+,CD4+,CD8+), B cells (CD19+), myeloid lineage cells (CD11b+) and megakaryocytes (GPIbα+).
Results: Sera of immunized mice showed a significant anti-αIIb immune response. Pups of immunized mice had low platelet counts, reduced body weight and bleeding diathesis. Ultrasound revealed miscarriage occurred mainly at E14.5 of immunized αIIb+/- fetuses. The miscarriage rate in our anti-αIIb mediated FNAIT model appeared significantly higher than the anti-β3 model. At E14.5, our results showed live fetuses of immunized mice had significantly lower body and liver weight although no significant difference in placental weight was observed. We found fetal liver HSCs have increased maternal antibody binding when incubated with sera from immunized αIIb-/- mice versus naïve αIIb-/- mice in vitro, suggesting that maternal anti-αIIb antibodies target fetal HSCs in vivo . Preliminary data also demonstrated that fetuses in the immunized group had reduced overall HSCs as well as αIIb+ HSC subsets in the placenta, liver and yolk sac. Fetal blood analysis showed reduced hematopoietic lineage cells in the immunized group, particularly T cells (CD3+), B cells and megakaryocytes.
Conclusions: We established an anti-αIIb mouse model of FNAIT and revealed a high rate of miscarriage, which may explain the paucity of reported human cases. Our results indicate maternal anti-αIIbantibodies may bind and target fetal HSCs during embryonic development, which contributes significantly to impaired placental and fetal liver development, and fetal death. Destruction of early αIIb+ HSC progenitors may explain the decrease in HSCs (both αIIb+ and αIIb-) and account for the pancytopenia in FNAIT fetuses. Further experiments are in progress to elucidate the mechanism by which destruction of αIIb+ HSCs contributes to fetal pathology.
*J.S. and B.E.O contributed equally to this work
No relevant conflicts of interest to declare.
Author notes
Asterisk with author names denotes non-ASH members.