Imprinting aberrations of SNRPN, ZAC1 and INPP5F genes involved in the pathogenesis of congenital heart disease with extracardiac malformations

Zhao, Xiaolei; Chang, Shaoyan; Liu, Xinli; Wang, Shuangxing; Zhang, Yueran; Lü, Xiaolin; Zhang, Ting; Zhang, Hui; Wang, Li

doi:10.1111/jcmm.15584

Cited by 11 publications

(9 citation statements)

References 32 publications

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“…A role for methylation and imprinting abnormalities in the etiology of structural birth defects is consistent with the occurrence of such conditions in imprinting syndromes (e.g., omphalocele in Beckwith-Wiedemann syndrome) 83 , 93 and has been suggested based on studies of non-syndromic structural birth defects. 94 , 95 , 96 , 97 Further, epigenetic and imprinting differences resulting from ARTs have been suggested as a potential cause for the increased risk of structural birth defects in offspring conceived by in vitro fertilization or intracytoplasmic sperm injection. 98 , 99 Consequently, it may be that any association between structural birth defects and MEGs is limited to the subset of MEGs that are involved in methylation and imprinting.…”

Section: Discussionmentioning

confidence: 99%

Maternal effect genes: Update and review of evidence for a link with birth defects

Mitchell

2022

Human Genetics and Genomics Advances

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Summary Maternal effect genes (MEGs) encode factors (e.g., RNA) that are present in the oocyte and required for early embryonic development. Hence, while these genes and gene products are of maternal origin, their phenotypic consequences result from effects on the embryo. The first mammalian MEGs were identified in the mouse in 2000 and were associated with early embryonic loss in the offspring of homozygous null females. In humans, the first MEG was identified in 2006, in women who had experienced a range of adverse reproductive outcomes, including hydatidiform moles, spontaneous abortions, and stillbirths. Over 80 mammalian MEGs have subsequently been identified, including several that have been associated with phenotypes in humans. In general, pathogenic variants in MEGs or the absence of MEG products are associated with a spectrum of adverse outcomes, which in humans range from zygotic cleavage failure to offspring with multi-locus imprinting disorders. Although less established, there is also evidence that MEGs are associated with structural birth defects (e.g., craniofacial malformations, congenital heart defects). This review provides an updated summary of mammalian MEGs reported in the literature through early 2021, as well as an overview of the evidence for a link between MEGs and structural birth defects.

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Section: Discussionmentioning

confidence: 99%

Maternal effect genes: Update and review of evidence for a link with birth defects

Mitchell

2022

Human Genetics and Genomics Advances

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“…Moreover, previous studies reported that SNHG14 and SNRPN are involved in the pathogenesis of cardiac hypertrophy and CHD, respectively. 27 , 28 These results indicated that A-to-I editing events during cardiomyocyte differentiation may also be related to cardiovascular diseases.…”

Section: Resultsmentioning

confidence: 85%

Global RNA editing identification and characterization during human pluripotent-to-cardiomyocyte differentiation

Chen

Liu

Qiao

et al. 2021

Molecular Therapy - Nucleic Acids

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RNA editing is widely involved in stem cell differentiation and development; however, RNA editing events during human cardiomyocyte differentiation have not yet been characterized and elucidated. Here, we identified genome-wide RNA editing sites and systemically characterized their genomic distribution during four stages of human cardiomyocyte differentiation. It was found that the expression level of ADAR1 affected the global number of adenosine to inosine (A-to-I) editing sites but not the editing degree. Next, we identified 43, 163, 544, and 141 RNA editing sites that contribute to changes in amino acid sequences, variation in alternative splicing, alterations in miRNA-target binding, and changes in gene expression, respectively. Generally, RNA editing showed a stage-specific pattern with 211 stage-shared editing sites. Interestingly, cardiac muscle contraction and heart-disease-related pathways were enriched by cardio-specific editing genes, emphasizing the connection between cardiomyocyte differentiation and heart diseases from the perspective of RNA editing. Finally, it was found that these RNA editing sites are also related to several congenital and noncongenital heart diseases. Together, our study provides a new perspective on cardiomyocyte differentiation and offers more opportunities to understand the mechanisms underlying cell fate determination, which can promote the development of cardiac regenerative medicine and therapies for human heart diseases.

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“…Another study on aberrations imprinting genes involved in the pathogenesis of CHD with extracardiac malformations also found the hypermethylation of INPP5F. In addition, risk analysis showed that abnormal hypermethylation of SNRPN and ZAC1 resulted in 5.545 and 7.438 times higher risks of CHD with extracardiac malformations [ 144 ].…”

Section: Dna Methylation Orchestrates Cardiomyocyte Development Maturation and Diseasementioning

confidence: 99%

The role of DNA methylation in syndromic and non-syndromic congenital heart disease

Cao

Huang

et al. 2021

Clin Epigenet

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Congenital heart disease (CHD) is a common structural birth defect worldwide, and defects typically occur in the walls and valves of the heart or enlarged blood vessels. Chromosomal abnormalities and genetic mutations only account for a small portion of the pathogenic mechanisms of CHD, and the etiology of most cases remains unknown. The role of epigenetics in various diseases, including CHD, has attracted increased attention. The contributions of DNA methylation, one of the most important epigenetic modifications, to CHD have not been illuminated. Increasing evidence suggests that aberrant DNA methylation is related to CHD. Here, we briefly introduce DNA methylation and CHD and then review the DNA methylation profiles during cardiac development and in CHD, abnormalities in maternal genome-wide DNA methylation patterns are also described. Whole genome methylation profile and important differentially methylated genes identified in recent years are summarized and clustered according to the sample type and methodologies. Finally, we discuss the novel technology for and prospects of CHD-related DNA methylation.

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Imprinting aberrations of SNRPN, ZAC1 and INPP5F genes involved in the pathogenesis of congenital heart disease with extracardiac malformations

Cited by 11 publications

References 32 publications

Maternal effect genes: Update and review of evidence for a link with birth defects

Maternal effect genes: Update and review of evidence for a link with birth defects

Global RNA editing identification and characterization during human pluripotent-to-cardiomyocyte differentiation

The role of DNA methylation in syndromic and non-syndromic congenital heart disease

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