Abstract
Preeclampsia is a major pregnancy-specific disorder affecting 5-7% of pregnancies worldwide. Although hypoxia caused by incomplete trophoblast invasion and impaired spiral arterial remodeling is thought to be a major cause of preeclampsia, how hypoxia affects placental development remains uncertain. GCM1 (glial cells missing homolog 1) is a transcription factor critical for placental development. In preeclampsia, GCM1 and its target genes syncytin 1 and placental growth factor, important for syncytiotrophoblast formation and placental vasculogenesis, are all decreased. Here we present evidence that GCM1 is a major target of hypoxia associated with preeclampsia. We show that hypoxia triggers GCM1 degradation by suppressing the phosphatidylinositol 3-kinase-Akt signaling pathway, leading to GSK-3beta activation. Activated GSK-3beta phosphorylates GCM1 on Ser322, which in turn recruits the F-box protein FBW2, leading to GCM1 ubiquitination and degradation. Importantly, the GSK-3beta inhibitor LiCl prevented hypoxia-induced GCM1 degradation. Our study identifies a molecular basis for the disrupted GCM1 transcription network in preeclampsia and provides a potential avenue for therapeutic intervention.
Highlights
Preeclampsia is a major pregnancy-specific disorder affecting 5–7% of pregnancies worldwide
Since hypoxia caused by incomplete trophoblast invasion and impaired spiral arterial remodeling is associated with preeclampsia [16, 17], we speculated that decreased GCM1 activity contributes to the pathogenesis of preeclampsia
To investigate whether GCM1 is a critical target of placental hypoxia, we first investigated the effects of hypoxia on GCM1 expression in the placental cell lines, JAR and BeWo, and in a BeWo line (BeWo31) stably expressing HA-tagged GCM1 (HA-GCM1) under the cytomegalovirus promoter
Summary
Preeclampsia is a major pregnancy-specific disorder affecting 5–7% of pregnancies worldwide. Decreased expression of GCM1 as well as its target genes, syncytin 1 and PGF, have been observed in preeclampsia and in placental cells under hypoxia [4, 11,12,13,14,15]. We show here that the PI3K-Akt pathway is inactivated under hypoxia, which results in activation of GSK-3 in placental cells.
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