Humanization of a tandem repeat in IG-DMR causes stochastic restoration of paternal imprinting at mouse Dlk1-Dio3 domain

Genome-wide DNA methylation and gene expression in human placentas derived from assisted reproductive technology

BACKGROUND

Assisted reproductive technology (ART) has been associated with increased risks for growth disturbance, disrupted imprinting as well as cardiovascular and metabolic disorders. However, the molecular mechanisms and whether they are a result of the ART procedures or the underlying subfertility are unknown.

METHODS

We performed genome-wide DNA methylation (EPIC Illumina microarrays) and gene expression (mRNA sequencing) analyses for a total of 80 ART and 77 control placentas. The separate analyses for placentas from different ART procedures and sexes were performed. To separate the effects of ART procedures and subfertility, 11 placentas from natural conception of subfertile couples and 12 from intrauterine insemination treatments were included.

RESULTS

Here we show that ART-associated changes in the placenta enriche in the pathways of hormonal regulation, insulin secretion, neuronal development, and vascularization. Observed decreased number of stromal cells as well as downregulated TRIM28 and NOTCH3 expressions in ART placentas indicate impaired angiogenesis and growth. DNA methylation changes in the imprinted regions and downregulation of TRIM28 suggest defective stabilization of the imprinting. Furthermore, downregulated expression of imprinted endocrine signaling molecule DLK1 associates with both ART and subfertility.

CONCLUSIONS

Decreased expressions of TRIM28, NOTCH3, and DLK1 bring forth potential mechanisms for several phenotypic features associated with ART. Our results support previous procedure specific findings: the changes associated with growth and metabolism link more prominently to the fresh embryo transfer with smaller placentas and newborns, than to the frozen embryo transfer with larger placentas and newborns. Furthermore, since the observed changes associate also with subfertility, they offer a precious insight to the molecular background of infertility.

Identification of responsible sequences which mutations cause maternal H19-ICR hypermethylation with Beckwith-Wiedemann syndrome-like overgrowth

Beckwith-Wiedemann syndrome (BWS) is caused by a gain of methylation (GOM) at the imprinting control region within the Igf2-H19 domain on the maternal allele (H19-ICR GOM). Mutations in the binding sites of several transcription factors are involved in H19-ICR GOM and BWS. However, the responsible sequence(s) for H19-ICR GOM with BWS-like overgrowth has not been identified in mice. Here, we report that a mutation in the SOX-OCT binding site (SOBS) causes partial H19-ICR GOM, which does not extend beyond CTCF binding site 3 (CTS3). Moreover, simultaneously mutating both SOBS and CTS3 causes complete GOM of the entire H19-ICR, leading to the misexpression of the imprinted genes, and frequent BWS-like overgrowth. In addition, CTS3 is critical for CTCF/cohesin-mediated chromatin conformation. These results indicate that SOBS and CTS3 are the sequences in which mutations cause H19-ICR GOM leading to BWS-like overgrowth and are essential for maintaining the unmethylated state of maternal H19-ICR.

Genetically humanized phenylketonuria mouse model as a testing tool for human genome editing in fertilized eggs

Targeted genome editing has made significant advancements; however, safety and ethical issues have not been fully elucidated, resulting in strict control of the technique. We tested genome editing tools on gametes from a genetically humanized mouse model using a phenylketonuria (PKU) mouse model to gain insights into genome editing in human embryos. The human PKU mouse model PahhR111X mice was generated. The junctional region between exon 3 and intron 3 of Pah was replaced with a 120 bp corresponding human PAH sequence, including the pathogenic common variant c.331C > T in PahhR111X mice. PahhR111X mice successfully recapitulated the PKU phenotype and showed cognitive dysfunction and depressive-like behavior, which are observed in human patients with PKU. Genome editing was applied to fertilized eggs of PahhR111X mice utilizing sgRNA that targets the human sequence. Mice with the corrected allele exhibited normal serum phenylalanine levels. Through genome editing, we validated the utility of sgRNA. The genetically humanized mouse model suggested that germ-line genome editing of the pathogenic variant may be feasible for monogenic disorders by revealing the recovery of the phenotype; however, there are remaining issues with the tool, including its efficiency and accuracy. This genome editing protocol using a genetically humanized mouse model will provide insights for improving current issues and contribute to the establishment of heritable human genome editing protocols.

Epigenome editing reveals core DNA methylation for imprinting control in the Dlk1-Dio3 imprinted domain

The Dlk1-Dio3 imprinted domain is controlled by an imprinting control region (ICR) called IG-DMR that is hypomethylated on the maternal allele and hypermethylated on the paternal allele. Although several genetic mutation experiments have shown that IG-DMR is essential for imprinting control of the domain, how DNA methylation itself functions has not been elucidated. Here, we performed both gain and loss of DNA methylation experiments targeting IG-DMR by transiently introducing CRISPR/Cas9 based-targeted DNA methylation editing tools along with one guide RNA into mouse ES cells. Altered DNA methylation, particularly at IG-DMR-Rep, which is a tandem repeat containing ZFP57 methylated DNA-binding protein binding motifs, affected the imprinting state of the whole domain, including DNA methylation, imprinted gene expression, and histone modifications. Moreover, the altered imprinting states were persistent through neuronal differentiation. Our results suggest that the DNA methylation state at IG-DMR-Rep, but not other sites in IG-DMR, is a master element to determine whether the allele behaves as the intrinsic maternal or paternal allele. Meanwhile, this study provides a robust strategy and methodology to study core DNA methylation in cis-regulatory elements, such as ICRs and enhancers.

Human SRY Expression at the Sex-determining Period is Insufficient to Drive Testis Development in Mice

The sex-determining region of the Y chromosome, Sry/SRY, is an initiation factor for testis development in both humans and mice. Although the functional compatibility between murine SRY and human SRY was previously examined in transgenic mice, their equivalency remains inconclusive. Because molecular interaction and timeline of mammalian sex determination were mostly described in murine experiments, we generated a mouse model in which Sry was substituted with human SRY to verify the compatibility. The mouse model had the human SRY open reading frame at the locus of murine Sry exon 1-Sry(SRY) mice-and was generated using the CRISPR/Cas9 system. The reproductive system of the mice was analyzed. The expression of human SRY in the fetal gonadal ridge of Sry(SRY) mice was detected. The external and internal genitalia of adult Sry(SRY) mice were similar to those of wild-type females, without any significant difference in anogenital distance. Sry(SRY) mice obtained gonads, which were morphologically considered as ovaries. Histological analysis revealed that the cortical regions of gonads from adult Sry(SRY) mice contained few follicles. We successfully replaced genes on the Y chromosome with targeted genome editing using the CRISPR/Cas9 system. Because the Sry(SRY) XY mice did not develop testis, we concluded that human SRY was insufficient to drive testis development in mouse embryos. The difference in response elements and lack of glutamine-rich domains may have invalidated human SRY function in mice. Signal transduction between Sry/SRY expression and Sox9/SOX9 activation is possibly organized in a species-specific manner.

Two sides of the Dlk1-Dio3 story in imprinting

Loss of imprinting (LOI) at the Dlk1-Dio3 locus is linked to Kagami-Ogata and Temple syndromes, and to cancer, but molecular mechanisms that prevent LOI are under-studied. In this issue of Developmental Cell, Aronson et al. demarcate the bipartite regulation of the Dlk1-Dio3 imprinting control region (ICR) IG-DMR, which maintains locus imprinting.