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
{"title":"减数分裂 I 的缺陷是雄激素性水滴形痣的成因之一。","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","doi":"10.1172/JCI170669","DOIUrl":null,"url":null,"abstract":"<p><p>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.</p>","PeriodicalId":15469,"journal":{"name":"Journal of Clinical Investigation","volume":null,"pages":null},"PeriodicalIF":13.3000,"publicationDate":"2024-11-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Defects in meiosis I contribute to the genesis of androgenetic hydatidiform moles.\",\"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\",\"doi\":\"10.1172/JCI170669\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>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. 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Defects in meiosis I contribute to the genesis of androgenetic hydatidiform moles.
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.
期刊介绍:
The Journal of Clinical Investigation, established in 1924 by the ASCI, is a prestigious publication that focuses on breakthroughs in basic and clinical biomedical science, with the goal of advancing the field of medicine. With an impressive Impact Factor of 15.9 in 2022, it is recognized as one of the leading journals in the "Medicine, Research & Experimental" category of the Web of Science.
The journal attracts a diverse readership from various medical disciplines and sectors. It publishes a wide range of research articles encompassing all biomedical specialties, including Autoimmunity, Gastroenterology, Immunology, Metabolism, Nephrology, Neuroscience, Oncology, Pulmonology, Vascular Biology, and many others.
The Editorial Board consists of esteemed academic editors who possess extensive expertise in their respective fields. They are actively involved in research, ensuring the journal's high standards of publication and scientific rigor.
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