Your search keyword '"Biaobang Chen"' showing total 3 results

1. Homozygous mutations in REC114 cause female infertility characterised by multiple pronuclei formation and early embryonic arrest.

Author

Wenjing Wang, Jie Dong, Biaobang Chen, Jing Du, Yanping Kuang, Xiaoxi Sun, Jing Fu, Bin Li, Jian Mu, Zhihua Zhang, Zhou Zhou, Zhao Lin, Ling Wu, Zheng Yan, Xiaoyan Mao, Qiaoli Li, Lin He, Lei Wang, and Qing Sang

Abstract

Background Abnormal pronuclear formation during fertilisation and subsequent early embryonic arrest results in female infertility. In recent years, with the prevalence of assisted reproductive technology, a few genes have been identified that are involved in female infertility caused by abnormalities in oocyte development, fertilisation and embryonic development. However, the genetic factors responsible for multiple pronuclei formation during fertilisation and early embryonic arrest remain largely unknown. Objective We aim to identify genetic factors responsible for multiple pronuclei formation during fertilisation or early embryonic arrest. Methods Whole-exome sequencing was performed in a cohort of 580 patients with abnormal fertilisation and early embryonic arrest. Effects of mutations were investigated in HEK293T cells by western blotting and immunoprecipitation, as well as minigene assay. Results We identified a novel homozygous missense mutation (c.397T>G, p.C133G) and a novel homozygous donor splice-site mutation (c.546+5G>A) in the meiotic gene REC114. REC114 is involved in the formation of double strand breaks (DSBs), which initiate homologous chromosome recombination. We demonstrated that the splice-site mutation affected the normal alternative splicing of REC114, while the missense mutation reduced the protein level of REC114 in vitro and resulted in the loss of its function to protect its partner protein MEI4 from degradation. Conclusions Our study has identified mutations in REC114 responsible for human multiple pronuclei formation and early embryonic arrest, and these findings expand our knowledge of genetic factors that are responsible for normal human female meiosis and fertility. [ABSTRACT FROM AUTHOR]

Published

2020

2. Mutations in NLRP2 and NLRP5 cause female infertility characterised by early embryonic arrest.

Author

Jian Mu, Wenjing Wang, Biaobang Chen, Ling Wu, Bin Li, Xiaoyan Mao, Zhihua Zhang, Jing Fu, Yanping Kuang, Xiaoxi Sun, Qiaoli Li, Li Jin, Lin He, Qing Sang, and Lei Wang

Abstract

Background Successful human reproduction requires normal spermatogenesis, oogenesis, fertilisation and early embryonic development, and abnormalities in any of these processes will result in infertility. Early embryonic arrest is commonly observed in infertile patients with recurrent failure of assisted reproductive technology (ART). However, the genetic basis for early embryonic arrest is largely unknown. Objective We aim to identify genetic causes of infertile patients characterised by early embryonic arrest. Methods We pursued exome sequencing in a proband with embryonic arrest from the consanguineous family. We further screened candidate genes in a cohort of 496 individuals diagnosed with early embryonic arrest by Sanger sequencing. Effects of mutations were investigated in HeLa cells, oocytes and embryos. Results We identified five independent individuals carrying biallelic mutations in NLRP2. We also found three individuals from two families carrying biallelic mutations in NLRP5. These mutations in NLRP2 and NLRP5 caused decreased protein expression in vitro and in oocytes and embryos. Conclusions NLRP2 and NLRP5 are novel mutant genes responsible for human early embryonic arrest. This finding provides additional potential diagnostic markers for patients with recurrent failure of ART and helps us to better understand the genetic basis of female infertility characterised by early embryonic arrest. [ABSTRACT FROM AUTHOR]

Published

2019

3. Mutations in TUBB8 cause a multiplicity of phenotypes in human oocytes and early embryos.

Author

Ruizhi Feng, Zheng Yan, Bin Li, Min Yu, Qing Sang, Guoling Tian, Yao Xu, Biaobang Chen, Ronggui Qu, Zhaogui Sun, Xiaoxi Sun, Li Jin, Lin He, Yanping Kuang, Cowan, Nicholas J., and Lei Wang

Abstract

Background TUBB8 is a primate-specific β-tubulin isotype whose expression is confined to oocytes and the early embryo. We previously found that mutations in TUBB8 caused oocyte maturation arrest. The objective was to describe newly discovered mutations in TUBB8 and to characterise the accompanying spectrum of phenotypes and modes of inheritance. Methods and results Patients with oocyte maturation arrest were sequenced with respect to TUBB8. We investigated the effects of identified mutations in vitro, in cultured cells and in mouse oocytes. Seven heterozygous missense and two homozygous mutations were identified. These mutations cause a range of folding defects in vitro, different degrees of microtubule disruption upon expression in cultured cells and interfere to varying extents in the proper assembly of the meiotic spindle in mouse oocytes. Several of the newly discovered TUBB8 mutations result in phenotypic variability. For example, oocytes harbouring any of three missense mutations (I210V, T238M and N348S) could extrude the first polar body. Moreover, they could be fertilised, although the ensuing embryos became developmentally arrested. Surprisingly, oocytes from patients harbouring homozygous TUBB8 mutations that in either case preclude the expression of a functional TUBB8 polypeptide nonetheless contained identifiable spindles. Conclusions Our data substantially expand the range of dysfunctional oocyte phenotypes incurred by mutation in TUBB8, underscore the independent nature of human oocyte meiosis and differentiation, extend the class of genetic diseases known as the tubulinopathies and provide new criteria for the qualitative evaluation of meiosis II (MII) oocytes for in vitro fertilization (IVF). [ABSTRACT FROM AUTHOR]

Published

2016