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Myometrial oxidative stress drives MED12 mutations in leiomyoma
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Myometrial oxidative stress drives MED12 mutations in leiomyoma
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Journal Article
Myometrial oxidative stress drives MED12 mutations in leiomyoma
2022
Overview
Background
More than 70% of leiomyomas (LM) harbor
MED12
mutations, primarily in exon 2 at c.130-131(GG). The cause of
MED12
mutations in myometrial cells remains largely unknown. We hypothesized that increased ROS promotes
MED12
mutations in myometrial cells through the oxidation of guanine nucleotides followed by misrepair.
Methods
Genomic oxidative burden (8-OHdG) was evaluated in vitro and in vivo by immunohistochemistry.
MED12
mutations were examined by Sanger sequencing and deep sequencing. Transcriptome examined by RNA-seq was performed in myometrium with and without LM, in primary myometrial cells treated with ROS. 8-OHdG mediated misrepair was analyzed by CRISPR/Cas9.
Results
Uteri with high LM burden had a significantly higher rate of
MED12
mutations than uteri with low LM burden. Compelling data suggest that the uterus normally produces reactive oxidative species (ROS) in response to stress, and ROS levels in LM are elevated due to metabolic defects. We demonstrated that genomic oxidized guanine (8-OHdG) was found at a significantly higher level in the myometrium of uteri that had multiple LM compared to myometrium without LM. Transcriptome and pathway analyses detected ROS stress in myometrium with LM. Targeted replacement of guanine with 8-OHdG at
MED12
c.130 by CRISPR/Cas9 significantly increased the misrepair of G>T. Exposure of primary myometrial cells to oxidative stress
in vitro
increased misrepair/mutations as detected by duplex sequencing.
Conclusions
Together, our data identified a clear connection between increased myometrial oxidative stress and a high rate of
MED12
mutations that may underlie the risk of LM development and severity in women of reproductive age.
Graphical Abstract
Highlights
High rate of
MED12
mutations and leiomyoma burden are clearly associated with myometrial oxidative stress.
MED12
mutations are driven by misrepair of 8-OHdG
at
c.130-c.131 detected by deep sequencing analysis both in vitro and in vivo.
