Defects in meiosis I contribute to the genesis of androgenetic hydatidiform moles
Maryam Rezaei, … , Teruko Taketo, Rima Slim
Maryam Rezaei, … , Teruko Taketo, Rima Slim
Published November 15, 2024
Citation Information: J Clin Invest. 2024;134(22):e170669. https://doi.org/10.1172/JCI170669.
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Research Article Genetics Reproductive biology

Defects in meiosis I contribute to the genesis of androgenetic hydatidiform moles

Abstract

To identify novel genes responsible for recurrent hydatidiform moles (HMs), we performed exome sequencing on 75 unrelated patients who were negative for mutations in the known genes. We identified biallelic deleterious variants in 6 genes, FOXL2, MAJIN, KASH5, SYCP2, MEIOB, and HFM1, in patients with androgenetic HMs, including a familial case of 3 affected members. Five of these genes are essential for meiosis I, and their deficiencies lead to premature ovarian insufficiency. Advanced maternal age is the strongest risk factor for sporadic androgenetic HM, which affects 1 in every 600 pregnancies. We studied Hfm1–/– female mice and found that these mice lost all their oocytes before puberty but retained some at younger ages. Oocytes from Hfm1–/– mice initiated meiotic maturation and extruded the first polar bodies in culture; however, their meiotic spindles were often positioned parallel, instead of perpendicular, to the ooplasmic membrane at telophase I, and some oocytes extruded the entire spindle with all the chromosomes into the polar bodies at metaphase II, a mechanism we previously reported in Mei1–/– oocytes. The occurrence of a common mechanism in two mouse models argues in favor of its plausibility at the origin of androgenetic HM formation in humans.

Authors

Maryam Rezaei, Manqi Liang, Zeynep Yalcin, Jacinta H. Martin, Parinaz Kazemi, Eric Bareke, Zhao-Jia Ge, Majid Fardaei, Claudio Benadiva, Reda Hemida, Adnan Hassan, Geoffrey J. Maher, Ebtesam Abdalla, William Buckett, Pierre-Adrien Bolze, Iqbaljit Sandhu, Onur Duman, Suraksha Agrawal, JianHua Qian, Jalal Vallian Broojeni, Lavi Bhati, Pierre Miron, Fabienne Allias, Amal Selim, Rosemary A. Fisher, Michael J. Seckl, Philippe Sauthier, Isabelle Touitou, Seang Lin Tan, Jacek Majewski, Teruko Taketo, Rima Slim

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Figure 4

Enrichment of monoallelic P/LP variants in genes with roles in DNA metabolism.

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Enrichment of monoallelic P/LP variants in genes with roles in DNA metab...
(A) Percentage of live births and pregnancy losses in patients negative for causative biallelic variants. (B) Detailed reproductive history of the 70 patients with RHM shown in A. Each patient is represented by a vertical bar on the x axis, and the number of each type of her pregnancy outcomes on the y axis. Asterisks denote the number of identified P/LP variants in the patient. (C) Proportional contribution of genes to the genetic susceptibility of the 310 analyzed patients. Numbers inside the pie indicate the number of patients with P/LP variants in each gene, and percentages outside the pie indicate the proportion of patients with P/LP variants in a given gene among the 310 patients. (D) Roles and functions of genes with P/LP variants based on GeneCards and PubMed. The numbers of variants in genes with the indicated functions are shown on the right of the bars. (E) The frequencies of P/LP variants in the 3 categories of patients. (F) Panther analysis showing a significant enrichment of monoallelic P/LP variants in the category of DNA metabolism in our patients while proteins from this category accounted for a smaller percentage in our input list. Statistical analysis was performed using 2-tailed Fisher’s exact test in A and χ2 test in F. P < 0.05 was considered significant.