A dominant negative mutation at the ATP binding domain of AMHR2 is associated with a defective anti-Mullerian hormone signaling pathway

Does a heterozygous mutation in AMHR2, identified in whole-exome sequencings (WES) of patients with primary ovarian insufficiency (POI), cause a defect in anti-Mullerian hormone (AMH) signaling? The I209N mutation at the adenosine triphosphate binding domain of AMHR2 exerts dominant negative defects in the AMH signaling pathway. Previous studies have demonstrated the associations of several sequence variants in AMH or AMHR2 with POI, but no functional assay has been performed to verify whether there was any defect on AMH signaling. Ninety-six unrelated female Chinese Han patients were diagnosed with idiopathic POI and subjected to WES. In silico analysis was done for the sequence variants followed by molecular assays to examine the functional effects of the sequence variants in human granulosa cells. In silico analysis, immunostaining, Western analysis, genome-wide expression analysis, quantitatively polymerase chain reaction were applied to the characterization of the sequence variants. We identified one novel heterozygous missense variant, p.Ala17Glu (A17E), in AMHR2. Subsequently, A17E and two independently reported missense variants, p.Ile209Asn (I209N) and p.Leu354Phe (L354F), were evaluated for effects on the AMH signaling pathway. In silico analysis predicted that all three variants may be deleterious. However, only one variant, I209N, showed severe defects in transducing the AMH signal as well as impaired SMAD1/5/8 phosphorylation. Furthermore, using genome-wide gene expression analysis, we identified genes whose expression was affected by the mutation, these included genes previously reported to participate in AMH signaling as well as newly identified genes. They are EMILIN2, FAM155A, GATA2, HES5, ID1, ID2, RLTPR, SMAD7, CBL, MALAT1 and SMARCA2. None. Although the in vitro assays demonstrated the causative effect of I209N on AMH signaling, further studies need to validate its long-term effects on folliculogenesis and POI. These results will aid both researchers and clinicians in understanding the molecular pathology of AMH signaling and POI to develop diagnostic assays or therapeutics approaches. Research funding is provided by the Ministry of Science and Technology of China [2012CB944704; 2012CB966702], and the National Natural Science Foundation of China [Grant number: 31171429]. The authors declare no conflict of interest.