Multiomics of Bohring-Opitz syndrome truncating ASXL1 mutations identify canonical and noncanonical Wnt signaling dysregulation
Isabella Lin, Angela Wei, Zain Awamleh, Meghna Singh, Aileen Ning, Analeyla Herrera, REACH Biobank and Registry, Bianca E. Russell, Rosanna Weksberg, Valerie A. Arboleda
Isabella Lin, Angela Wei, Zain Awamleh, Meghna Singh, Aileen Ning, Analeyla Herrera, REACH Biobank and Registry, Bianca E. Russell, Rosanna Weksberg, Valerie A. Arboleda
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Research Article Development Genetics

Multiomics of Bohring-Opitz syndrome truncating ASXL1 mutations identify canonical and noncanonical Wnt signaling dysregulation

Abstract

ASXL1 (additional sex combs–like 1) plays key roles in epigenetic regulation of early developmental gene expression. De novo protein-truncating mutations in ASXL1 cause Bohring-Opitz syndrome (BOS; OMIM #605039), a rare neurodevelopmental condition characterized by severe intellectual disabilities, distinctive facial features, hypertrichosis, increased risk of Wilms tumor, and variable congenital anomalies, including heart defects and severe skeletal defects giving rise to a typical BOS posture. These BOS-causing ASXL1 variants are also high-prevalence somatic driver mutations in acute myeloid leukemia. We used primary cells from individuals with BOS (n = 18) and controls (n = 49) to dissect gene regulatory changes caused by ASXL1 mutations using comprehensive multiomics assays for chromatin accessibility (ATAC-seq), DNA methylation, histone methylation binding, and transcriptome in peripheral blood and skin fibroblasts. Our data show that regardless of cell type, ASXL1 mutations drive strong cross-tissue effects that disrupt multiple layers of the epigenome. The data showed a broad activation of canonical Wnt signaling at the transcriptional and protein levels and upregulation of VANGL2, which encodes a planar cell polarity pathway protein that acts through noncanonical Wnt signaling to direct tissue patterning and cell migration. This multiomics approach identifies the core impact of ASXL1 mutations and therapeutic targets for BOS and myeloid leukemias.

Authors

Isabella Lin, Angela Wei, Zain Awamleh, Meghna Singh, Aileen Ning, Analeyla Herrera, REACH Biobank and Registry, Bianca E. Russell, Rosanna Weksberg, Valerie A. Arboleda

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Figure 5

Truncated ASXL1 dysregulates the canonical and noncanonical Wnt signaling pathways.

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Truncated ASXL1 dysregulates the canonical and noncanonical Wnt signalin...
(A) The canonical Wnt signaling pathway (left) is activated when Wnt ligand stimulates its receptors. This inactivates the β-catenin destruction complex, allowing nuclear translocation of β-catenin and activation of target genes. Van Gogh–like 2 (VANGL2) intersects with the canonical pathway through activation of Dishevelled (DVL) to activate noncanonical pathways (right) and cell migration. (B) Whole-cell lysate (15 μg) of representative BOS- (n = 5) and control-derived (n = 5) fibroblasts show downstream Wnt pathway activation at the protein level through staining for VANGL2, β-catenin, axis-inhibition protein 1 (AXIN1), AXIN2, DVL2, and DVL3. (C) ImageJ (NIH) quantification identified an increase of 1.5-fold for AXIN1, 2.8-fold for AXIN2, 3.5-fold for DVL2, and 1.5-fold for DVL3 averaged across BOS patient samples compared to controls. This was repeated 2 times. In BOS patient samples, the Wnt pathway coreceptor LRP5 (green) transcriptional upregulation in (D) blood (log2FC = 1.64, Padj = 3.58 × 10–9) and (E) fibroblast RNA-seq and (F) DNA hypomethylation in blood (Δβ –3.5% to –8.0%, FDR < 0.05) at multiple CpG sites. Similarly, LRP6 (green) shows that transcriptional upregulation in (G) blood RNA-seq (log2FC = 1.63, Padj = 1.17 × 10–12), (H) fibroblast RNA-seq, and (I) DNA hypomethylation in blood (Δβ –2.7% to –4.0%, FDR < 0.05) BOS samples exhibit strong dysregulation of VANGL2 across tissue and assay types (pink). For BOS samples, VANGL2 is (J) hypomethylated (Δβ –7.6%) at CpG site cg17024258, and shows (K) increased chromatin accessibility at the 5′ UTR (log2FC = 1.20). VANGL2 has significant transcriptional upregulation in (L) blood RNA-seq (log2FC = 3.80) and (M) fibroblast RNA-seq (log2FC = 2.55). In representative BOS patient samples, the VANGL2 promoter shows (N) increased chromatin accessibility and (O) increased H3K4me3 marks compared with control. The box-and-whisker plots in DI, L, and M show the mean (horizontal line), range (whiskers), and IQR [upper and lower box boundaries]. LRP5 RNA-seq blood: control, 25.6 (18.3–39.1) [20.7–30.4]; BOS, 84.2 (24.1–134.6) [72.8–106.8]. LRP5 RNA-seq fibroblast: control, 3829 (2996–5177) [3187–4351]; BOS, 4392 (2824–5390) [4268–4719]. LRP6 RNA-seq blood: control, 75.0 (32.2–110.1) [67.8–86.6]; BOS, 234.5 (123.1–346.3) [199.9–266.9]. LRP6 RNA-seq fibroblast: control, 2804 (2286–3262) [2602–3094]; BOS, 2904 (2381–3596) [2725–3006]. VANGL2 RNA-seq blood: control: 2.3 (0–5.7) [0–4.1]; BOS, 35.3 (10.1–51.8) [27.2–45.2]. VANGL2 RNA-seq fibroblast: control, 134.8 (39.4–282.8) [90.8–163.4]; BOS, 1002.7 (464–1235.6) [894.7–1210.1].