Development of super-specific epigenome editing by targeted allele-specific DNA methylation.

IF 4.2 2区 生物学 Q1 GENETICS & HEREDITY
Nivethika Rajaram, Alexandra G Kouroukli, Susanne Bens, Pavel Bashtrykov, Albert Jeltsch
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引用次数: 1

Abstract

Background: Epigenome editing refers to the targeted reprogramming of genomic loci using an EpiEditor which may consist of an sgRNA/dCas9 complex that recruits DNMT3A/3L to the target locus. Methylation of the locus can lead to a modulation of gene expression. Allele-specific DNA methylation (ASM) refers to the targeted methylation delivery only to one allele of a locus. In the context of diseases caused by a dominant mutation, the selective DNA methylation of the mutant allele could be used to repress its expression but retain the functionality of the normal gene.

Results: To set up allele-specific targeted DNA methylation, target regions were selected from hypomethylated CGIs bearing a heterozygous SNP in their promoters in the HEK293 cell line. We aimed at delivering maximum DNA methylation with highest allelic specificity in the targeted regions. Placing SNPs in the PAM or seed regions of the sgRNA, we designed 24 different sgRNAs targeting single alleles in 14 different gene loci. We achieved efficient ASM in multiple cases, such as ISG15, MSH6, GPD1L, MRPL52, PDE8A, NARF, DAP3, and GSPT1, which in best cases led to five to tenfold stronger average DNA methylation at the on-target allele and absolute differences in the DNA methylation gain at on- and off-target alleles of > 50%. In general, loci with the allele discriminatory SNP positioned in the PAM region showed higher success rate of ASM and better specificity. Highest DNA methylation was observed on day 3 after transfection followed by a gradual decline. In selected cases, ASM was stable up to 11 days in HEK293 cells and it led up to a 3.6-fold change in allelic expression ratios.

Conclusions: We successfully delivered ASM at multiple genomic loci with high specificity, efficiency and stability. This form of super-specific epigenome editing could find applications in the treatment of diseases caused by dominant mutations, because it allows silencing of the mutant allele without repression of the expression of the normal allele thereby minimizing potential side-effects of the treatment.

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通过靶向等位基因特异性DNA甲基化开发超特异性表观基因组编辑。
背景:表观基因组编辑是指使用表观编辑器对基因组基因座进行靶向重编程,表观编辑器可能由将DNMT3A/3L募集到靶基因座的sgRNA/dCas9复合物组成。基因座的甲基化可以导致基因表达的调节。等位基因特异性DNA甲基化(ASM)是指仅对一个基因座的一个等位基因进行靶向甲基化递送。在显性突变引起的疾病中,突变等位基因的选择性DNA甲基化可以用来抑制其表达,但保留正常基因的功能。结果:为了建立等位基因特异性靶向DNA甲基化,在HEK293细胞系中,从低甲基化的CGI中选择了在其启动子中携带杂合SNP的靶区。我们的目标是在靶区提供具有最高等位基因特异性的最大DNA甲基化。将SNPs置于sgRNA的PAM或种子区,我们设计了24种不同的sgRNA,靶向14个不同基因座中的单个等位基因。我们在多种情况下实现了有效的ASM,如ISG15、MSH6、GPD1L、MRPL52、PDE8A、NARF、DAP3和GSPT1,这在最佳情况下导致靶上等位基因的平均DNA甲基化增强5到10倍 > 50%。一般来说,等位基因歧视性SNP位于PAM区域的基因座显示出更高的ASM成功率和更好的特异性。在转染后第3天观察到最高的DNA甲基化,随后逐渐下降。在选定的病例中,ASM在HEK293细胞中稳定达11天,并导致等位基因表达率变化3.6倍。结论:我们成功地在多个基因组位点递送ASM,具有高特异性、高效性和稳定性。这种形式的超特异性表观基因组编辑可以应用于治疗显性突变引起的疾病,因为它可以在不抑制正常等位基因表达的情况下沉默突变等位基因,从而最大限度地减少治疗的潜在副作用。
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来源期刊
Epigenetics & Chromatin
Epigenetics & Chromatin GENETICS & HEREDITY-
CiteScore
7.00
自引率
0.00%
发文量
35
审稿时长
1 months
期刊介绍: Epigenetics & Chromatin is a peer-reviewed, open access, online journal that publishes research, and reviews, providing novel insights into epigenetic inheritance and chromatin-based interactions. The journal aims to understand how gene and chromosomal elements are regulated and their activities maintained during processes such as cell division, differentiation and environmental alteration.
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