Intergenic sequences harboring potential enhancer elements contribute to Axenfeld-Rieger syndrome by regulating PITX2
Yizheng Jiang, Yu Peng, Qi Tian, Zhe Cheng, Bei Feng, Junping Hu, Lu Xia, Hui Guo, Kun Xia, Liang Zhou, Zhengmao Hu
Yizheng Jiang, Yu Peng, Qi Tian, Zhe Cheng, Bei Feng, Junping Hu, Lu Xia, Hui Guo, Kun Xia, Liang Zhou, Zhengmao Hu
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Research Article Genetics Ophthalmology

Intergenic sequences harboring potential enhancer elements contribute to Axenfeld-Rieger syndrome by regulating PITX2

Abstract

Recent studies have uncovered that noncoding sequence variants may relate to Axenfeld-Rieger syndrome (ARS), a rare developmental anomaly with genetic heterogeneity. However, how these genomic regions are functionally and structurally associated with ARS is still unclear. In this study, we performed genome-wide linkage analysis and whole-genome sequencing in a Chinese family with ARS and identified a heterozygous deletion of about 570 kb (termed LOH-1) in the intergenic sequence between paired-like homeodomain transcription factor 2 (PITX2) and family with sequence similarity 241 member A. Knockout of LOH-1 homologous sequences caused ARS phenotypes in mice. RNA-Seq and real-time quantitative PCR revealed a significant reduction in Pitx2 gene expression in LOH-1–/– mice, while forkhead box C1 expression remained unchanged. ChIP-Seq and bioinformatics analysis identified a potential enhancer region (LOH-E1) within LOH-1. Deletion of LOH-E1 led to a substantial downregulation of the PITX2 gene. Mechanistically, we found a sequence (hg38 chr4:111,399,594–111,399,691) that is on LOH-E1 could regulate PITX2 by binding to RAD21, a critical component of the cohesin complex. Knockdown of RAD21 resulted in reduced PITX2 expression. Collectively, our findings indicate that a potential enhancer sequence that is within LOH-1 may regulate PITX2 expression remotely through cohesin-mediated loop domains, leading to ARS when absent.

Authors

Yizheng Jiang, Yu Peng, Qi Tian, Zhe Cheng, Bei Feng, Junping Hu, Lu Xia, Hui Guo, Kun Xia, Liang Zhou, Zhengmao Hu

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Figure 5

P2, which is within LOH-E1, could bind RAD21 to regulate the expression of PITX2.

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P2, which is within LOH-E1, could bind RAD21 to regulate the expression ...
(A) Venn diagram presents transcription factors (TFs) that bind to both the LOH-E1 enhancer region and the PITX2 core promoter region. (B) Peptide spectrum match (PSM) of peptide from RAD21 protein by liquid chromatography mass spectrometry (LC-MS) in the DNA pulldown. (C) RT-qPCR detection of RAD21 expression following its downregulation in HEK293 cells through siRNAs. For detection of RAD21 expression level, RAD21_small interfering RNA 2 (RAD21_si2) or RAD21_si3 compared with small interfering RNA negative control (siNC), respectively. n = 3 for each group. Data were analyzed using 1-way ANOVA. (D) RT-qPCR detection of PITX2A, PITX2B, and PITX2C expression after the downregulation of RAD21 in HEK293 cells through RAD21_si2 and RAD21_si3. n = 3 for each group. Data were analyzed using 1-way ANOVA. (E) Identification of the potential RAD21 binding sequence within the LOH-E1 region; the position of the red line can match the RAD21 motif. (F) ChIP-qPCR assay for the binding of RAD21 to the P2 and surrounding regions. Quantitative PCR detection for the enrichment of the P1, P2, and P3 regions within LOH-E1 upon anti-RAD21 ChIP and IgG in the HEK293 cell line. P1 and P3 are the upstream and downstream random regions of P2. JJ is indicated by the red rectangle. n = 3 for each group. All data are represented as mean ± SEM.