Stochastic anomaly of methylome but persistent SRY hypermethylation in disorder of sex development in canine somatic cell nuclear transfer.

Young-Soo Jeong ,Kang Bae Park,Jung Hyun Park,Yeon Woo Jeong,Chi-Hun Park,Shujia Huang,In Sung Hwang,Desheng Gong,Nam Hyung Kim,Huanming Yang,Eun Ji Choi,Mi Na Kang,Woo Suk Hwang,Changjong Moon,Fei Gao,Hanlin Lu,Joung Joo Kim,Huijuan Luo,Meiyan Li,Sang‐Hwan Hyun ,Eui‐Bae Jeung ,Kwang Hee Ko ,Si Yang Liu

doi:10.1038/srep31088

Abstract

Somatic cell nuclear transfer (SCNT) provides an excellent model for studying epigenomic reprogramming during mammalian development. We mapped the whole genome and whole methylome for potential anomalies of mutations or epimutations in SCNT-generated dogs with XY chromosomal sex but complete gonadal dysgenesis, which is classified as 78, XY disorder of sex development (DSD). Whole genome sequencing revealed no potential genomic variations that could explain the pathogenesis of DSD. However, extensive but stochastic anomalies of genome-wide DNA methylation were discovered in these SCNT DSD dogs. Persistent abnormal hypermethylation of the SRY gene was observed together with its down-regulated mRNA and protein expression. Failure of SRY expression due to hypermethylation was further correlated with silencing of a serial of testis determining genes, including SOX9, SF1, SOX8, AMH and DMRT1 in an early embryonic development stage at E34 in the XYDSD gonad, and high activation of the female specific genes, including FOXL2, RSPO1, CYP19A1, WNT4, ERα and ERβ, after one postnatal year in the ovotestis. Our results demonstrate that incomplete demethylation on the SRY gene is the driving cause of XYDSD in these XY DSD dogs, indicating a central role of epigenetic regulation in sex determination.

Highlights

Mammalian sex determination, which is the genetic process by which gonadal primordia are committed to differentiate into either testes or ovaries, is governed by complex molecular networks of gene expression[1]
Our results clearly indicated the central role of epigenetic regulation on SRY in sex determination, as well as the importance of the epigenomic reprogramming during early embryonic development
Cytogenetic and phenotypic analyses of disorder of sex development (DSD) dogs generated by somatic cell nuclear transfer (SCNT)

Summary

Introduction

Mammalian sex determination, which is the genetic process by which gonadal primordia are committed to differentiate into either testes or ovaries, is governed by complex molecular networks of gene expression[1]. The products of testis and ovary specific genes antagonize each other and promote testis and ovary development Disturbance of this equilibrium can lead to disorders of sex development (DSDs)[2]. A specific molecular diagnosis currently only be made in ~20% of patients with DSDs. Cloned animals generated by somatic cell nuclear transfer (SCNT) technology provide an alternative model as cases of anomalies in the sex differentiation of animals have reportedly occurred during SCNT procedure for unknown reasons[6]. Cloned animals generated by somatic cell nuclear transfer (SCNT) technology provide an alternative model as cases of anomalies in the sex differentiation of animals have reportedly occurred during SCNT procedure for unknown reasons[6] This evokes questions about early events of epigenetic reprogramming in SCNT when the chromosomal sex is clearly determined in genetic donor cells. Our results clearly indicated the central role of epigenetic regulation on SRY in sex determination, as well as the importance of the epigenomic reprogramming during early embryonic development

Methods

Results

Conclusion