Non-coding cause of congenital heart defects: Abnormal RNA splicing with multiple isoforms as a mechanism for heterotaxy

Non-coding cause of congenital heart defects: Abnormal RNA splicing with multiple isoforms as a mechanism for heterotaxy

Heterotaxy is a disorder characterized by severe congenital heart defects (CHDs) and abnormal left-right patterning in other thoracic or abdominal organs. Clinical and research-based genetic testing has previously focused on evaluation of coding variants to identify causes of CHDs, leaving non-codin...

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Veröffentlicht in:HGG advances 2024-10, Vol.5 (4), p.100353, Article 100353
Hauptverfasser: Wells, John R., Padua, Maria B., Haaning, Allison M., Smith, Amanda M., Morris, Shaine A., Tariq, Muhammad, Ware, Stephanie M.
Format: Artikel
Sprache:eng
Schlagworte:
alternative splicing
Animals
cardiovascular system
Female
Heart Defects, Congenital - genetics
Heterotaxy Syndrome - genetics
Homeodomain Proteins - genetics
Homeodomain Proteins - metabolism
Humans
intronic variant
left-right patterning
Male
Pedigree
Protein Isoforms - genetics
pseudoexon inclusion
RNA Splicing - genetics
Transcription Factors - genetics
Transcription Factors - metabolism
X-linked disease
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container_end_page
container_issue 4
container_start_page 100353
container_title HGG advances
container_volume 5
creator Wells, John R.
Padua, Maria B.
Haaning, Allison M.
Smith, Amanda M.
Morris, Shaine A.
Tariq, Muhammad
Ware, Stephanie M.
description Heterotaxy is a disorder characterized by severe congenital heart defects (CHDs) and abnormal left-right patterning in other thoracic or abdominal organs. Clinical and research-based genetic testing has previously focused on evaluation of coding variants to identify causes of CHDs, leaving non-coding causes of CHDs largely unknown. Variants in the transcription factor zinc finger of the cerebellum 3 (ZIC3) cause X-linked heterotaxy. We identified an X-linked heterotaxy pedigree without a coding variant in ZIC3. Whole-genome sequencing revealed a deep intronic variant (ZIC3 c.1224+3286A>G) predicted to alter RNA splicing. An in vitro minigene splicing assay confirmed the variant acts as a cryptic splice acceptor. CRISPR-Cas9 served to introduce the ZIC3 c.1224+3286A>G variant into human embryonic stem cells demonstrating pseudoexon inclusion caused by the variant. Surprisingly, Sanger sequencing of the resulting ZIC3 c.1224+3286A>G amplicons revealed several isoforms, many of which bypass the normal coding sequence of the third exon of ZIC3, causing a disruption of a DNA-binding domain and a nuclear localization signal. Short- and long-read mRNA sequencing confirmed these initial results and identified additional splicing patterns. Assessment of four isoforms determined abnormal functions in vitro and in vivo while treatment with a splice-blocking morpholino partially rescued ZIC3. These results demonstrate that pseudoexon inclusion in ZIC3 can cause heterotaxy and provide functional validation of non-coding disease causation. Our results suggest the importance of non-coding variants in heterotaxy and the need for improved methods to identify and classify non-coding variation that may contribute to CHDs. Coding variants in the transcription factor ZIC3 cause X-linked heterotaxy, a laterality defect causing congenital anomalies. Functional genomic analyses of a ZIC3 intronic variant identified in an X-linked heterotaxy pedigree demonstrated pseudoexon inclusion leading to RNA-splicing disruption, highlighting the importance of whole-genome sequencing to identify potential disease-causing variants.
doi_str_mv 10.1016/j.xhgg.2024.100353
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Clinical and research-based genetic testing has previously focused on evaluation of coding variants to identify causes of CHDs, leaving non-coding causes of CHDs largely unknown. Variants in the transcription factor zinc finger of the cerebellum 3 (ZIC3) cause X-linked heterotaxy. We identified an X-linked heterotaxy pedigree without a coding variant in ZIC3. Whole-genome sequencing revealed a deep intronic variant (ZIC3 c.1224+3286A&gt;G) predicted to alter RNA splicing. An in vitro minigene splicing assay confirmed the variant acts as a cryptic splice acceptor. CRISPR-Cas9 served to introduce the ZIC3 c.1224+3286A&gt;G variant into human embryonic stem cells demonstrating pseudoexon inclusion caused by the variant. Surprisingly, Sanger sequencing of the resulting ZIC3 c.1224+3286A&gt;G amplicons revealed several isoforms, many of which bypass the normal coding sequence of the third exon of ZIC3, causing a disruption of a DNA-binding domain and a nuclear localization signal. Short- and long-read mRNA sequencing confirmed these initial results and identified additional splicing patterns. Assessment of four isoforms determined abnormal functions in vitro and in vivo while treatment with a splice-blocking morpholino partially rescued ZIC3. These results demonstrate that pseudoexon inclusion in ZIC3 can cause heterotaxy and provide functional validation of non-coding disease causation. Our results suggest the importance of non-coding variants in heterotaxy and the need for improved methods to identify and classify non-coding variation that may contribute to CHDs. Coding variants in the transcription factor ZIC3 cause X-linked heterotaxy, a laterality defect causing congenital anomalies. 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Clinical and research-based genetic testing has previously focused on evaluation of coding variants to identify causes of CHDs, leaving non-coding causes of CHDs largely unknown. Variants in the transcription factor zinc finger of the cerebellum 3 (ZIC3) cause X-linked heterotaxy. We identified an X-linked heterotaxy pedigree without a coding variant in ZIC3. Whole-genome sequencing revealed a deep intronic variant (ZIC3 c.1224+3286A&gt;G) predicted to alter RNA splicing. An in vitro minigene splicing assay confirmed the variant acts as a cryptic splice acceptor. CRISPR-Cas9 served to introduce the ZIC3 c.1224+3286A&gt;G variant into human embryonic stem cells demonstrating pseudoexon inclusion caused by the variant. Surprisingly, Sanger sequencing of the resulting ZIC3 c.1224+3286A&gt;G amplicons revealed several isoforms, many of which bypass the normal coding sequence of the third exon of ZIC3, causing a disruption of a DNA-binding domain and a nuclear localization signal. Short- and long-read mRNA sequencing confirmed these initial results and identified additional splicing patterns. Assessment of four isoforms determined abnormal functions in vitro and in vivo while treatment with a splice-blocking morpholino partially rescued ZIC3. These results demonstrate that pseudoexon inclusion in ZIC3 can cause heterotaxy and provide functional validation of non-coding disease causation. Our results suggest the importance of non-coding variants in heterotaxy and the need for improved methods to identify and classify non-coding variation that may contribute to CHDs. Coding variants in the transcription factor ZIC3 cause X-linked heterotaxy, a laterality defect causing congenital anomalies. 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source MEDLINE; DOAJ Directory of Open Access Journals; Elektronische Zeitschriftenbibliothek - Frei zugängliche E-Journals; PubMed Central; Alma/SFX Local Collection
subjects alternative splicing
Animals
cardiovascular system
Female
Heart Defects, Congenital - genetics
Heterotaxy Syndrome - genetics
Homeodomain Proteins - genetics
Homeodomain Proteins - metabolism
Humans
intronic variant
left-right patterning
Male
Pedigree
Protein Isoforms - genetics
pseudoexon inclusion
RNA Splicing - genetics
Transcription Factors - genetics
Transcription Factors - metabolism
X-linked disease
title Non-coding cause of congenital heart defects: Abnormal RNA splicing with multiple isoforms as a mechanism for heterotaxy
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